© 2014 Dialog Semiconductor 1 www.dialog-semiconductor.com
DA14580 Low Power Bluetooth Smart SoC
DATASHEET -
General description
The DA14580 integrated circuit has a fully integrated
radio transceiver and baseband processor for Blue-
tooth® Smart. It can be used as a standalone applica-
tion processor or as a data pump in hosted systems.
The DA14580 supports a flexible memory architecture
for storing Bluetooth profiles and custom application
code, which can be updated over the air (OTA). The
qualified Bluetooth Smart protocol stack is stored in a
dedicated ROM. All software runs on the ARM® Cor-
tex®-M0 processor via a simple scheduler.
The Bluetooth Smart firmware includes the L2CAP ser-
vice layer protocols, Security Manager (SM), Attribute
Protocol (ATT), the Generic Attribute Profile (GATT)
and the Generic Access Profile (GAP). All profiles pub-
lished by the Bluetooth SIG as well as custom profiles
are supported.
The transceiver interfaces directly to the antenna and
is fully compliant with the Bluetooth 4.1 standard.
The DA14580 has dedicated hardware for the Link
Layer implementation of Bluetooth Smart and interface
controllers for enhanced connectivity capabilities.
Features
Complies with Bluetooth V4.1, ETSI EN 300 328 and
EN 300 440 Class 2 (Europe), FCC CFR47 Part 15
(US) and ARIB STD-T66 (Japan)
Processing power
16 MHz 32 bit ARM Cortex-M0 with SWD inter-
face
Dedicated Link Layer Processor
AES-128 bit encryption Processor
Memories
32 kB One-Time-Programmable (OTP) memory
42 kB System SRAM
84 kB ROM
8 kB Retention SRAM
Power management
Integrated Buck/Boost DC-DC converter
P0, P1, P2 and P3 ports with 3.3 V tolerance
Easy decoupling of only 4 supply pins
Supports coin (typ. 3.0 V) and alkaline (typ. 1.5 V)
battery cells
10-bit ADC for battery voltage measurement
Digital controlled oscillators
16 MHz crystal (±20 ppm max) and RC oscillator
32 kHz crystal (±50 ppm, ±500 ppm max) and
RCX oscillator
General purpose, Capture and Sleep timers
Digital interfaces
General purpose I/Os: 14 (WLCSP34 package),
24 (QFN40 package), 32 (QFN48 package)
2 UARTs with hardware flow control up to 1 MBd
SPI+™ interface
I2C bus at 100 kHz, 400 kHz
3-axes capable Quadrature Decoder
Analog interfaces
4-channel 10-bit ADC
Radio transceiver
Fully integrated 2.4 GHz CMOS transceiver
Single wire antenna: no RF matching or RX/TX
switching required
Supply current at VBAT3V:
TX: 3.4 mA, RX: 3.7 mA (with ideal DC-DC)
0 dBm transmit output power
-20 dBm output power in “Near Field Mode”
-93 dBm receiver sensitivity
Packages:
WLCSP 34 pins, 2.436 mm x 2.436 mm
QFN 40 pins, 5 mm x 5 mm
QFN 48 pins, 6 mm x 6 mm
KGD (wafer, dice)
________________________________________________________________________________________________
System diagram
JANUARY 29, 2015 V3.1
DA14580
Low Power Bluetooth Smart SoC
FINAL
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 2 Final - January 29, 2015 v3.1
1. Block diagram. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Pinout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
3. System overview . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
3.1 ARM CORTEXM0 CPU . . . . . . . . . . . . . . . . . . 9
3.2 BLUETOOTH SMART. . . . . . . . . . . . . . . . . . . . 9
3.2.1 BLE Core . . . . . . . . . . . . . . . . . . . . . . . . . 9
3.2.2 Radio Transceiver . . . . . . . . . . . . . . . . . 10
3.2.3 SmartSnippets
3.3 MEMORIES . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
3.4 FUNCTIONAL MODES . . . . . . . . . . . . . . . . . . 11
3.5 POWER MODES. . . . . . . . . . . . . . . . . . . . . . . 12
3.6 INTERFACES . . . . . . . . . . . . . . . . . . . . . . . . . 12
3.6.1 UARTs . . . . . . . . . . . . . . . . . . . . . . . . . . 12
3.6.2 SPI+ . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
3.6.3 I2C interface . . . . . . . . . . . . . . . . . . . . . 12
3.6.4 General purpose ADC . . . . . . . . . . . . . . 13
3.6.5 Quadrature decoder. . . . . . . . . . . . . . . . 13
3.6.6 Keyboard controller . . . . . . . . . . . . . . . . 13
3.6.7 Input/output ports . . . . . . . . . . . . . . . . . . 13
3.7 TIMERS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
3.7.1 General purpose timers . . . . . . . . . . . . . 13
3.7.2 Wake-Up timer . . . . . . . . . . . . . . . . . . . . 14
3.7.3 Watchdog timer . . . . . . . . . . . . . . . . . . . 14
3.8 CLOCK/RESET . . . . . . . . . . . . . . . . . . . . . . . . 14
3.8.1 Clocks . . . . . . . . . . . . . . . . . . . . . . . . . . 14
3.8.2 Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
3.9 POWER MANAGEMENT . . . . . . . . . . . . . . . . 15
4. Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
5. Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . 142
6. Package information . . . . . . . . . . . . . . . . . . . . . . 154
6.1 MOISTURE SENSITIVITY LEVEL (MSL) . . . 154
6.2 WLCSP HANDLING . . . . . . . . . . . . . . . . . . . 154
6.3 SOLDERING INFORMATION . . . . . . . . . . . . 154
6.4 PACKAGE OUTLINES . . . . . . . . . . . . . . . . . 155
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 3 Final - January 29, 2015 v3.1
1. Block diagram
Figure 1 DA14580 block diagram
24 April 2012
ARM Cortex M0
SWD (JTAG)
CORE POReset
BLE Core
LINK LAYER
HARDWARE
AES-128
Radio
Transceiver
APB bridge
POWER/CLOCK
Management (PMU)
DCDC
(BUCK/BOOST)
GPIO MULTIPLEXING
XTAL
16 MHz
XTAL
32.768 kHz
RC
32 kHz
SW TIMER
GP ADC
SPI
ROM
84 KB
System/
Exchange
RAM
42 KB
Ret. RAM
2 KB
RC
16 MHz
Memory Controller
OTP
32 KB
DMA
OTPC
QUAD
DECODER
LDO
SYS
LDO
RET
LDO
SYS
LDO
SYS
LDO
RF
WAKE UP
TIMER
Ret. RAM2
3 KB
Ret. RAM3
2 KB
Ret. RAM4
1 KB
KEYBOARD
CTRL
UART
FIFO
UART2
FIFO
I2C
FIFO
RCX
Timer 0
1xPWM
Timer 2
3xPWM
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 4 Final - January 29, 2015 v3.1
2. Pinout
The DA14580 comes in three packages:
1. A Wafer Level Chip Scale Package (WLCSP) with
34 balls
2. A Quad Flat Package No Leads (QFN) with 48 pins
3. A Quad Flat Package No Leads (QFN) with 40 pins
The actual pin/ball assignment is depicted in the follow-
ing figures:
Figure 2 WLCSP34 ball assignment
12345
A
B
C
D
E
6
F
RFIOm
RFIOp
XTAL16Mm
XTAL16Mp
SW_CLK
SWDIO
VBAT1V
SWITCH
VDCDC_RF
P1_3
P1_2
P1_1
P1_0
VDCDC
GND
GND
RST
VBAT_RF
GND
VBAT3V
XTAL32Kp
XTAL32Km
GND
P0_1
P0_2
P0_4
P0_7
VPP
P0_0
P0_3
P0_5
P0_6
GND GND
Figure 3 QFN48 pin assignment
Pin 0: GND plane
RFIOp
DA14580
(Top View)
9
8
7
6
5
4
3
2
P0_1
P0_2
P0_3
P3_0
P0_4
P0_5
P0_6
11
10
P0_7
P2_1
P3_1
1
12
14
15
16
17
18
19
20
21
XTAL32Kp
P2_2
VBAT_RF
P3_4
VBAT3V
GND
RST
P2_3 22
23
XTAL32Km
VDCDC
13
24
28
29
30
31
32
33
34
35 XTAL16Mm
XTAL16Mp
P1_3
P1_2
SW_CLK
SWDIO
P1_1
VBAT1V
26
27
SWITCH
P1_0
36
25
NC
VPP
P2_8
P2_7
RFIOm
P2_6
P2_5
47
P3_7
P2_9
46
45
44
43
42
41
40
39
38
P0_0
P3_2
VDCDC_RF
37
48 P2_0
P3_3
P2_4
P3_5
P3_6
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 5 Final - January 29, 2015 v3.1
Figure 4 QFN40 pin assignment
11
12
13
14
15
16
17
18
8
7
6
5
4
3
2
1
23
24
25
26
27
28
29
30
Pin 0: GND
plane
P2_7
P0_0
P0_1
P0_2
P0_3
NC
P0_4
P2_1
XTAL16Mm
XTAL16Mp
P1_3
P1_2
SW_CLK
SWDIO
P1_1
VBAT1V
XTAL32Kp
P2_2
VBAT_RF
VBAT3V
GND
RST
P2_3
VDCDC
P2_9
VPP
P2_8
RFIOp
RFIOm
P2_6
P2_5
40
10
9
P0_7
19
20
21
22
VDCDC_RF
P2_0
XTAL32Km
P2_4
SWITCH
P1_0
DA14580
(Top View)
39
38
37
36
35
34
33
32
31
P0_5
P0_6
Table 1: Ordering information (samples)
Part number Package Size (mm) Shipment form Pack quantity
DA14580-01UNA WLSCP34 2.436 x 2.436 Mini-reel 50/100/1000
DA14580-01A31 QFN48 6 x 6 Tray 50
DA14580-01AT1 QFN40 5 x 5 Tray 50
Table 2: Ordering information (production)
Part number Package Size (mm) Shipment form Pack quantity
DA14580-01UNA WLSCP34 2.436 x 2.436 Mini-reel 5000
DA14580-01A32 QFN48 6 x 6 Reel 4000
DA14580-01AT2 QFN40 5 x 5 Reel 5000
DA14580-01WO4 KGD wafer Contact Dialog Semiconductor sales office
DA14580-01WC4 KGD dice Contact Dialog Semiconductor sales office
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 6 Final - January 29, 2015 v3.1
Table 3: Pin Description
PIN NAME TYPE Drive
(mA)
Reset
state
(Note )
DESCRIPTION
General Purpose I/Os
P0_0
P0_1
P0_2
P0_3
P0_4
P0_5
P0_6
P0_7
DIO
DIO
DIO
DIO
DIO
DIO
DIO
DIO
4.8 I-PD
I-PD
I-PD
I-PD
I-PD
I-PD
I-PD
I-PD
INPUT/OUTPUT with selectable pull up/down resistor. Pull-down
enabled during and after reset. General purpose I/O port bit or
alternate function nodes. Contains state retention mechanism
during power down.
P1_0
P1_1
P1_2
P1_3
P1_4/SWCLK
P1_5/SW_DIO
DIO
DIO
DIO
DIO
DIO
DIO
4.8 I-PD
I-PD
I-PD
I-PD
I-PD
I-PU
INPUT/OUTPUT with selectable pull up/down resistor. Pull-down
enabled during and after reset. General purpose I/O port bit or
alternate function nodes. Contains state retention mechanism
during power down.
This signal is the JTAG clock by default
This signal is the JTAG data I/O by default
P2_0
P2_1
P2_2
P2_3
P2_4
P2_5
P2_6
P2_7
P2_8
P2_9
DIO
DIO
DIO
DIO
DIO
DIO
DIO
DIO
DIO
DIO
4.8 I-PD
I-PD
I-PD
I-PD
I-PD
I-PD
I-PD
I-PD
I-PD
I-PD
INPUT/OUTPUT with selectable pull up/down resistor. Pull-down
enabled during and after reset. General purpose I/O port bit or
alternate function nodes. Contains state retention mechanism
during power down.
NOTE: This port is only available on the QFN40/QFN48 pack-
ages.
P3_0
P3_1
P3_2
P3_3
P3_4
P3_5
P3_6
P3_7
DIO
DIO
DIO
DIO
DIO
DIO
DIO
DIO
4.8 I-PD
I-PD
I-PD
I-PD
I-PD
I-PD
I-PD
I-PD
INPUT/OUTPUT with selectable pull up/down resistor. Pull-down
enabled during and after reset. General purpose I/O port bit or
alternate function nodes. Contain state retention mechanism dur-
ing power down.
NOTE: This port is only available on the QFN48 package.
Debug interface
SWDIO/P1_5 DIO 4.8 I-PU INPUT/OUTPUT. JTAG Data input/output. Bidirectional data and
control communication. Can also be used as a GPIO
SW_CLK/
P1_4
DIO 4.8 I-PD INPUT JTAG clock signal. Can also be used as a GPIO
Clocks
XTAL16Mp AI INPUT. Crystal input for the 16 MHz XTAL
XTAL16Mm AO OUTPUT. Crystal output for the 16 MHz XTAL
XTAL32kp AI INPUT. Crystal input for the 32.768 kHz XTAL
XTAL32km AO OUTPUT. Crystal output for the 32.768 kHz XTAL
Quadrature decoder
QD_CHA_X DI INPUT. Channel A for the X axis. Mapped on Px ports
QD_CHB_X DI INPUT. Channel B for the X axis. Mapped on Px ports
QD_CHA_Y DI INPUT. Channel A for the Y axis. Mapped on Px ports
QD_CHB_Y DI INPUT. Channel B for the Y axis. Mapped on Px ports
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 7 Final - January 29, 2015 v3.1
QD_CHA_Z DI INPUT. Channel A for the Z axis. Mapped on Px ports
QD_CHB_Z DI INPUT. Channel B for the Z axis. Mapped on Px ports
SPI bus interface
SPI_CLK DO INPUT/OUTPUT. SPI Clock. Mapped on Px ports
SPI_DI DI INPUT. SPI Data input. Mapped on Px ports
SPI_DO DO OUTPUT. SPI Data output. Mapped on Px ports
SPI_EN DI INPUT. SPI Clock enable (active LOW). Mapped on Px ports
I2C bus interface
SDA DIO/DIOD INPUT/OUTPUT. I2C bus Data with open drain port. Mapped on
Px ports
SCL DIO/DIOD INPUT/OUTPUT. I2C bus Clock with open drain port. In open
drain mode, SCL is monitored to support bit stretching by a
slave. Mapped on Px ports.
UART interface
UTX DO OUTPUT. UART transmit data. Mapped on Px ports
URX DI INPUT. UART receive data. Mapped on Px ports
URTS DO OUTPUT. UART Request to Send. Mapped on Px ports
UCTS DI INPUT. UART Clear to Send. Mapped on Px ports
UTX2 DO OUTPUT. UART 2 transmit data. Mapped on Px ports
URX2 DI INPUT. UART 2 receive data. Mapped on Px ports
URTS2 DO OUTPUT. UART 2 Request to Send. Mapped on Px ports
UCTS2 DI INPUT. UART 2 Clear to Send. Mapped on Px ports
Analog interface
ADC[0] AI INPUT. Analog to Digital Converter input 0. Mapped on P0[0]
ADC[1] AI INPUT. Analog to Digital Converter input 1. Mapped on P0[1]
ADC[2] AI INPUT. Analog to Digital Converter input 2. Mapped on P0[2]
ADC[3] AI INPUT. Analog to Digital Converter input 3. Mapped on P0[3]
Radio transceiver
RFIOp AIO RF input/output. Impedance 50
RFIOm AIO RF ground
Miscellaneous
RST DI INPUT. Reset signal (active high). Must be connected to GND if
not used.
VBAT_RF AIO Connect to VBAT3V on the PCB
VDCDC_RF AIO Connect to VDCDC on the PCB
VPP AI INPUT. This pin is used while OTP programming and testing.
OTP programming: VPP = 6.8 V ± 0.25 V
OTP Normal operation: leave VPP floating
Power supply
VBAT3V AIO INPUT/OUTPUT. Battery connection. Used for a single coin bat-
tery (3 V). If an alkaline or a NiMH battery (1.5 V) is attached to
pin VBAT1V, this is the second output of the DC-DC converter.
Table 3: Pin Description
PIN NAME TYPE Drive
(mA)
Reset
state
(Note )
DESCRIPTION
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 8 Final - January 29, 2015 v3.1
VBAT1V AI INPUT. Battery connection. Used for an alkaline or a NiMh bat-
tery (1.5 V). If a single coin battery (3 V) is attached to pin
VBAT3V,this pin must be connected to GND.
SWITCH AIO INPUT/OUTPUT. Connection for the external DC-DC converter
inductor.
VDCDC AO Output of the DC-DC converter
GND AIO - - Ground
Table 3: Pin Description
PIN NAME TYPE Drive
(mA)
Reset
state
(Note )
DESCRIPTION
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 9 Final - January 29, 2015 v3.1
3. System overview
The DA14580 contains the following internal blocks:
3.1 ARM CORTEXM0 CPU
The Cortex-M0 processor is a 32-bit Reduced Instruc-
tion Set Computing (RISC) processor with a von Neu-
mann architecture (single bus interface). It uses an
instruction set called Thumb, which was first supported
in the ARM7TDMI processor; however, several newer
instructions from the ARMv6 architecture and a few
instructions from the Thumb-2 technology are also
included. Thumb-2 technology extended the previous
Thumb instruction set to allow all operations to be car-
ried out in one CPU state. The instruction set in
Thumb-2 includes both 16-bit and 32-bit instructions;
most instructions generated by the C compiler use the
16-bit instructions, and the 32-bit instructions are used
when the 16-bit version cannot carry out the required
operations. This results in high code density and
avoids the overhead of switching between two instruc-
tion sets.
In total, the Cortex-M0 processor supports only 56
base instructions, although some instructions can have
more than one form. Although the instruction set is
small, the Cortex-M0 processor is highly capable
because the Thumb instruction set is highly optimized.
Academically, the Cortex-M0 processor is classified as
load-store architecture, as it has separate instructions
for reading and writing to memory, and instructions for
arithmetic or logical operations that use registers.
Features
• Thumb instruction set. Highly efficient, high code
density and able to execute all Thumb instructions
from the ARM7TDMI processor.
• High performance. Up to 0.9 DMIPS/MHz (Dhrys-
tone 2.1) with fast multiplier.
• Built-in Nested Vectored Interrupt Controller (NVIC).
This makes interrupt configuration and coding of
exception handlers easy. When an interrupt request
is taken, the corresponding interrupt handler is exe-
cuted automatically without the need to determine
the exception vector in software.
• Interrupts can have four different programmable pri-
ority levels. The NVIC automatically handles nested
interrupts.
• The design is configured to respond to exceptions
(e.g. interrupts) as soon as possible (minimum 16
clock cycles).
• Non maskable interrupt (NMI) input for safety critical
systems.
• Easy to use and C friendly. There are only two
modes (Thread mode and Handler mode). The
whole application, including exception handlers, can
be written in C without any assembler.
• Built-in System Tick timer for OS support. A 24-bit
timer with a dedicated exception type is included in
the architecture, which the OS can use as a tick
timer or as a general timer in other applications with-
out an OS.
• SuperVisor Call (SVC) instruction with a dedicated
SVC exception and PendSV (Pendable SuperVisor
service) to support various operations in an embed-
ded OS.
• Architecturally defined sleep modes and instructions
to enter sleep. The sleep features allow power con-
sumption to be reduced dramatically. Defining sleep
modes as an architectural feature makes porting of
software easier because sleep is entered by a spe-
cific instruction rather than implementation defined
control registers.
• Fault handling exception to catch various sources of
errors in the system.
• Support for 24 interrupts.
• Little endian memory support.
• Wake up Interrupt Controller (WIC) to allow the pro-
cessor to be powered down during sleep, while still
allowing interrupt sources to wake up the system.
• Halt mode debug. Allows the processor activity to
stop completely so that register values can be
accessed and modified. No overhead in code size
and stack memory size.
• CoreSight technology. Allows memories and periph-
erals to be accessed from the debugger without halt-
ing the processor.
• Supports Serial Wire Debug (SWD) connections.
The serial wire debug protocol can handle the same
debug features as the JTAG, but it only requires two
wires and is already supported by a number of
debug solutions from various tools vendors.
• Four (4) hardware breakpoints and two (2) watch
points.
• Breakpoint instruction support for an unlimited num-
ber of software breakpoints.
• Programmer’s model similar to the ARM7TDMI pro-
cessor. Most existing Thumb code for the
ARM7TDMI processor can be reused. This also
makes it easy for ARM7TDMI users, as there is no
need to learn a new instruction set.
3.2 BLUETOOTH SMART
3.2.1 BLE Core
The BLE (Bluetooth Low Energy) core is a qualified
Bluetooth baseband controller compatible with the
Bluetooth Smart specification and it is in charge of
packet encoding/decoding and frame scheduling.
Features
• All device classes support (Broadcaster, Central,
Observer, Peripheral)
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 10 Final - January 29, 2015 v3.1
• All packet types (Advertising / Data / Control)
• Encryption (AES / CCM)
• Bit stream processing (CRC, Whitening)
• FDMA/TDMA/events formatting and synchronization
• Frequency hopping calculation
• Operating clock 16 MHz or 8 MHz
• Low power modes supporting 32.0 kHz or
32.768 kHz
• Supports power down of the baseband during the
protocol’s idle periods
• AHB Slave interface for register file access
• AHB Slave interface for Exchange Memory access
of CPU via BLE core
• AHB Master interface for direct access of BLE core
to Exchange Memory space
3.2.2 Radio Transceiver
The Radio Transceiver implements the RF part of the
Bluetooth Smart protocol. Together with the Bluetooth
4.0 PHY layer, this provides a 93 dB RF link budget for
reliable wireless communication.
All RF blocks are supplied by on-chip low-drop out-reg-
ulators (LDOs). The bias scheme is programmable per
block and optimized for minimum power consumption.
The Bluetooth LE radio comprises the Receiver, Trans-
mitter, Synthesizer, Rx/Tx combiner block, and Biasing
LDOs.
Features
• Single ended RFIO interface, 50 matched
• Alignment free operation
• -93 dBm receiver sensitivity
• 0 dBm transmit output power
• Ultra low power consumption
• Fast frequency tuning minimises overhead
3.2.3 SmartSnippets
The DA14580 comes complete with Dialog’s Smart-
Snippets Bluetooth Software platform which includes
a qualified Bluetooth Smart single-mode stack on chip.
Numerous Bluetooth Smart profiles for consumer well-
ness, sport, fitness, security and proximity applications
are supplied as standard, while additional customer
profiles can be developed and added as needed.
The SmartSnippets software development environ-
ment is based on Keil’s uVision mature tools and
contains example application code for both embedded
and hosted modes.
Apart from the protocol stack, the Software platform
supports a Hardware Abstraction Layer (HAL) which
enables easy access to peripheral’s features from a
programmer’s point of view, as presented in the follow-
ing figure.
Figure 5 SmartSnippets stack
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 11 Final - January 29, 2015 v3.1
Core drivers are provided for each interface of the
DA14580 enabling optimized usage of the hardware’s
capabilities. These drivers provide an easy-to-use
interface towards the hardware engines without having
to interfere with the register programming directly.
On top of the core drivers, a number of sample drivers
is also provided enabling communication with basic
Bluetooth Smart application components: accelerome-
ters, FLASH/EEPROM non-volatile memories, etc.
3.3 MEMORIES
The following memories are part of the DA14580’s
internal blocks:
ROM. This is a 84 kB ROM containing the Bluetooth
Smart protocol stack as well as the boot code
sequence.
OTP. This is a 32 kB One-Time Programmable mem-
ory array, used to store the application code as well as
Bluetooth Smart profiles. It also contains the system
configuration and calibration data.
System SRAM. This is a 42 kB system SRAM (Sys-
RAM) which is primarily used for mirroring the program
code from the OTP when the system wakes/powers
up. It also serves as Data RAM for intermediate varia-
bles and various data that the protocol requires.
Optionally, it can be used as extra memory space for
the BLE TX and RX data structures.
Retention RAMs. These are 4 special low leakage
SRAM cells (2 kB + 2 kB + 3 kB + 1 kB) used to store
various data of the Bluetooth Smart protocol as well as
the system’s global variables and processor stack
when the system goes into Deep Sleep mode. Storage
of this data ensures secure and quick configuration of
the BLE Core after the system wakes up. Every cell
can be powered on or off according to the application
needs for retention area when in Deep Sleep mode.
3.4 FUNCTIONAL MODES
The DA14580 is optimized for deeply embedded appli-
cations such as health monitoring, sports measuring,
human interaction devices etc. Customers are able to
develop and test their own applications. Upon comple-
tion of the development, the application code can be
programmed into the OTP. In general, the system has
three functional modes of operation:
A. Development mode: During this phase application
code is developed using the ARM Cortex-M0 SW envi-
ronment. The compiled code is then downloaded into
the System RAM or any Retention RAMs by means of
SWD (JTAG) or any serial interface (e.g. UART).
Address 0x00 is remapped to the physical memory that
contains the code and the CPU is configured to reset
and execute code from the remapped device. This
mode is enabling application development, debugging
and on-the-fly testing.
B. Normal mode: After the application is ready and
verified, the code can be burned into the OTP. When
the system boots/wakes up, the DMA of the OTP con-
troller will automatically copy the program code from
the OTP into the system RAM. Next, a SW reset or a
jump to the System RAM occurs and code execution is
started. Hence, in this mode, the system is autono-
mous, contains the required SW in OTP and is ready
for integration into the final product.
C. Calibration mode: Between Development and Nor-
mal mode, there is an intermediate stage where the
chip needs to be calibrated with respect to two impor-
tant features:
• Programming of the Bluetooth device address
• Programming of the trimming value for the external
16 MHz crystal.
This mode of operation applies to the final product and
is performed by the customer. During this phase, cer-
Figure 6 Hardware abstraction layer
GPIO
Driver
Application
Accelerometer
Driver
SPI
Driver
UART
Driver
SPIFLASH
Driver
ADC
Driver
Battery
Driver
Quadrature
EEPROM
I2C
Driver
Sample
Drivers
CORE
Drivers
Timers
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 12 Final - January 29, 2015 v3.1
tain fields in the OTP should be programmed
3.5 POWER MODES
There are four different power modes in the DA14580:
•Active mode: System is active and operates at full
speed.
•Sleep mode: No power gating has been pro-
grammed, the ARM CPU is idle, waiting for an inter-
rupt. PD_SYS is on. PD_PER and PED_RAD
depending on the programmed enabled value.
•Extended Sleep mode: All power domains are off
except for the PD_AON, the programmed PD_RRx
and the PD_SR. Since the SysRAM retains its data,
no OTP mirroring is required upon waking up the
system.
•Deep Sleep mode: All power domains are off except
for the PD_AON and the programmed PD_RRx.
This mode dissipates the minimum leakage power.
However, since the SysRAM has not retained its
data, an OTP mirror action is required upon waking
up the system.
3.6 INTERFACES
3.6.1 UARTs
The UART is compliant to the industry-standard 16550
and is used for serial communication with a peripheral,
modem (data carrier equipment, DCE) or data set.
Data is written from a master (CPU) over the APB bus
to the UART and it is converted to serial form and
transmitted to the destination device. Serial data is also
received by the UART and stored for the master (CPU)
to read back.
There is no DMA support on the UART block since its
contains internal FIFOs. Both UARTs support hard-
ware flow control signals (RTS, CTS, DTR, DSR).
Features
• 16 bytes Transmit and receive FIFOs
• Hardware flow control support (CTS/RTS)
• Shadow registers to reduce software overhead and
also include a software programmable reset
• Transmitter Holding Register Empty (THRE) inter-
rupt mode
• IrDA 1.0 SIR mode supporting low power mode.
• Functionality based on the 16550 industry standard:
• Programmable character properties, such as num-
ber of data bits per character (5-8), optional
• parity bit (with odd or even select) and number of
stop bits (1, 1.5 or 2)
• Line break generation and detection
• Prioritized interrupt identification
• Programmable serial data baud rate as calculated
by the following: baud rate = (serial clock frequency)/
(divisor).
3.6.2 SPI+
This interface supports a subset of the Serial Periph-
eral Interface (SPITM). The serial interface can transmit
and receive 8, 16 or 32 bits in master/slave mode and
transmit 9 bits in master mode. The SPI+ interface has
enhanced functionality with bidirectional 2x16-bit word
FIFOs.
SPI is a trademark of Motorola, Inc.
Features
• Slave and Master mode
• 8 bit, 9 bit, 16 bit or 32 bit operation
• Clock speeds upto 16 MHz for the SPI controller.
Programmable output frequencies of SPI source
clock divided by 1, 2, 4, 8
• SPI clock line speed up to 8 MHz
• SPI mode 0, 1, 2, 3 support (clock edge and phase)
• Programmable SPI_DO idle level
• Maskable Interrupt generation
• Bus load reduction by unidirectional writes-only and
reads-only modes.
Built-in RX/TX FIFOs for continuous SPI bursts.
3.6.3 I2C interface
The I2C interface is a programmable control bus that
provides support for the communications link between
Integrated Circuits in a system. It is a simple two-wire
bus with a software-defined protocol for system control,
which is used in temperature sensors and voltage level
translators to EEPROMs, general-purpose I/O, A/D
and D/A converters.
Features
• Two-wire I2C serial interface consists of a serial data
line (SDA) and a serial clock (SCL)
• Two speeds are supported:
• Standard mode (0 to 100 kbit/s)
• Fast mode (<= 400 kbit/s)
• Clock synchronization
• 32 deep transmit/receive FIFOs
• Master transmit, Master receive operation
• 7 or 10-bit addressing
• 7 or 10-bit combined format transfers
• Bulk transmit mode
• Default slave address of 0x055
• Interrupt or polled-mode operation
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 13 Final - January 29, 2015 v3.1
• Handles Bit and Byte waiting at both bus speeds
• Programmable SDA hold time
3.6.4 General purpose ADC
The DA14580 is equipped with a high-speed ultra low
power 10-bit general purpose Analog-to-Digital Con-
verter (GPADC). It can operate in unipolar (single
ended) mode as well as in bipolar (differential) mode.
The ADC has its own voltage regulator (LDO) of 1.2 V,
which represents the full scale reference voltage.
Features
• 10-bit dynamic ADC with 65 ns conversion time
• Maximum sampling rate 3.3 Msample/s
• Ultra low power (5 A typical supply current at
100 ksample/s)
• Single-ended as well as differential input with two
input scales
• Four single-ended or two differential external input
channels
• Battery monitoring function
• Chopper function
• Offset and zero scale adjust
• Common-mode input level adjust
3.6.5 Quadrature decoder
This block decodes the pulse trains from a rotary
encoder to provide the step and the direction of the
movement of an external device. Three axes (X, Y, Z)
are supported.
The integrated quadrature decoder can automatically
decode the signals for the X, Y and Z axes of a HID
input device, reporting step count and direction: the
channels are expected to provide a pulse train with 90
degrees phase difference; depending on whether the
reference channel is leading or lagging, the direction
can be determined.
This block can be used for waking up the chip as soon
as there is any kind of movement from the external
device connected to it.
Features
• Three 16-bit signed counters that provide the step
count and direction on each of the axes (X, Y and Z)
• Programmable system clock sampling at maximum
16 MHz.
• APB interface for control and programming
• Programmable source from P0, P1 and P2 ports
• Digital filter on the channel inputs to avoid spikes
3.6.6 Keyboard controller
The Keyboard controller can be used for debouncing
the incoming GPIO signals when implementing a key-
board scanning engine. It generates an interrupt to the
CPU (KEYBR_IRQ).
In parallel, five extra interrupt lines can be triggered by
a state change on 32 selectable GPIOs (GPIOx_IRQ).
Features
• Monitors any of the 32 available GPIOs (12 in the
WLCSP package, 22 in the QFN40 and 32 in the
QFN48)
• Generates a keyboard interrupt on key press or key
release
• Implements debouncing time from 0 upto 63 ms
• Supports five separate interrupt generation lines
from GPIO toggling
3.6.7 Input/output ports
The DA14580 has software-configurable I/O pin
assignment, organized into ports Port 0, Port1, Port2
and Port 3. Port 2 is only available at the QFN40 pack-
age while ports 2 and 3 are available at the QFN48
package.
Features
• Port 0: 8 pins, Port 1: 6 pins (including SW_CLK and
SWDIO), Port 2: 10 pins, Port 3: 8 pins
• Fully programmable pin assignment
• Selectable 25 k pull-up, pull-down resistors per pin
• Pull-up voltage either VBAT3V (BUCK mode) or
VBAT1V (BOOST mode) configurable per pin
• Fixed assignment for analog pin ADC[3:0]
• Pins retain their last state when system enters the
Extended or Deep Sleep mode.
3.7 TIMERS
3.7.1 General purpose timers
The Timer block contains 2 timer modules that are soft-
ware controlled, programmable and can be used for
various tasks.
Timer 0
• 16-bit general purpose timer
• Ability to generate 2 Pulse Width Modulated signals
(PWM0 and PWM1, with common programming)
• Programmable output frequency:
f16, 8, 4, 2 MHz or 32 kHz
M1+N1++
------------------------------------------------------------------------=
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 14 Final - January 29, 2015 v3.1
with N = 0 to (216-1), M = 0 to (216-1)
• Programmable duty cycle:
• Separately programmable interrupt timer:
Timer 2
• 14-bit general purpose timer
• Ability to generate 3 Pulse Width Modulated signals
(PWM2, PWM3 and PWM4)
• Input clock frequency:
with N = 1, 2, 4 or 8
and sys_clk = 16 MHz or 32 kHz
• Programmable output frequency:
• Three outputs with Programmable duty cycle from
0 % to 100 %
• Used for white LED intensity (on/off) control
3.7.2 Wake-Up timer
The Wake-up timer can be programmed to wake up the
DA14580 from power down mode after a prepro-
grammed number of GPIO events.
Features
• Monitors any GPIO state change
• Implements debouncing time from 0 upto 63 ms
• Accumulates external events and compares the
number to a programmed value
• Generates an interrupt to the CPU
3.7.3 Watchdog timer
The Watchdog timer is an 8-bit timer with sign bit that
can be used to detect an unexpected execution
sequence caused by a software run-away and can
generate a full system reset or a Non-Maskable Inter-
rupt (NMI).
Features
• 8 bits down counter with sign bit, clocked with a
10.24 ms clock for a maximum 2.6 s time-out.
• Non-Maskable Interrupt (NMI) or WDOG reset.
• Optional automatic WDOG reset if NMI handler fails
to update the Watchdog register.
• Non-maskable Watchdog freeze of the Cortex-M0
Debug module when the Cortex-M0 is halted in
Debug state.
Maskable Watchdog freeze by user program. Note that
if the system is not remapped, i.e. SysRAM is at
address 0x20000000, then a watchdog fire will trigger
the BootROM code to be executed again.
3.8 CLOCK/RESET
3.8.1 Clocks
The Digital Controlled Xtal Oscillator (DXCO) is a
Pierce configured type of oscillator designed for low
power consumption and high stability. There are two
such crystal oscillators in the system, one at 16
MHz(XTAL16M) and a second at 32.768 kHz
(XTAL32K). The 32.768 kHz oscillator has no trimming
capabilities and is used as the clock of the Extended/
Deep Sleep modes. The 16 MHz oscillator can be
trimmed.
The principle schematic of the two oscillators is shown
in Figure 7 below. No external components to the
DA14580 are required other than the crystal itself. If
the crystal has a case connection, it is advised to con-
nect the case to ground.
There are 3 RC oscillators in the DA14580: one provid-
ing 16 MHz (RC16M), one providing 32 kHz (RC32K)
and one providing a frequency in the range of 10.5 kHz
(RCX).
3.8.2 Reset
The DA14580 comprises an RST pad which is active
high. It contains an RC filter for spikes suppression
with 400 k and 2.8 pF for the resistor and the capaci-
tor respectively. It also contains a 25 k pull-down
resistor. This pad should be connected to ground if not
needed by the application. The typical latency of the
RST pad is in the range of 2 s.
M1+
M1+N1++
-------------------------------------------- 100 %=
T16, 8, 4, 2 MHz or 32 kHz
ON 1+
------------------------------------------------------------------------=
fIN
sys_clk
N
-------------------=
fOUT
fIN
2
------
to fIN
214 1–
------------------
=
Figure 7 Crystal oscillator circuits
XTAL16Mp
clock16MHz
XTAL16Mm
16 MHz
XTAL32Kp
clock32kHz
XTAL32Km
32.768 kHz
0-22.4 pF
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 15 Final - January 29, 2015 v3.1
3.9 POWER MANAGEMENT
The DA14580 has a complete power management
function integrated with Buck or Boost DC-DC con-
verter and separate LDOs for the different power
domains of the system.
Features
• On-chip LDOs, without external capacitors
• Synchronous DC-DC converter which can be config-
ured as either:
• Boost (step-up) converter, starting from 0.9 V,
when running from an Alkaline/NiMH cell.
• Buck (step-down) converter for increased effi-
ciency when running from a Lithium coin-cell or 2
Alkaline batteries down to 2.35 V.
• Battery voltage measurement ADC (multiplexed
input from general purpose ADC)
• Use of small external components (2.2 H inductor
and 1F capacitor)
The Power Block contains a DC-DC converter which
can be configured to operate as a Step-Up or a Step-
Down converter. The converter provides power to four
LDO groups in the system:
1. LDO RET: This is the LDO providing power to the
Retention domain (PD_AON). It powers the Retention
RAMs and the digital part which is always on.
2. LDO OTP: This is the LDO powering the OTP macro
cell. This is the reason for using the step-up DC-DC
converter when running from an Alkaline battery.
3. LDO SYS: This is the LDO providing the system with
the actual VDD power required for the digital part to
operate. Note that the Power Block implements seam-
less switching from the LDO SYS to the LDO RET
when the system enters Deep Sleep mode. In the latter
case, a low voltage is applied to the PD_AON power
domain to further reduce leakage.
4. LDO (various): This a group of LDOs used for the
elaborate control of the powering up/down of the
Radio, the GP ADC and the XTAL16M oscillator.
There are two ways of connecting external batteries to
the Power Block of the DA14580. They depend on the
specific battery cell used and its voltage range. Battery
cells are distinguished into Lithium coin cells (2.35 V to
3.3 V) and Alkaline cells (1.0 V to 1.8 V). The connec-
tion diagrams are presented in Figure 9 and Figure 8
respectively:
Figure 8 Supply overview, Coin-cell application
Buck Converter
LDO
VBAT1V
SWITCH
VBAT3V
VDCDC
LDO LDO
Lithium
coin-cell
digital analog/RF
retention
2.35 V to 3.3 V
DA14580
VDCDC_RF
VBAT_RF
analog/RF
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 16 Final - January 29, 2015 v3.1
The usage of Boost or Buck mode with respect to the
provided voltage ranges is illustrated in the following
figure which also illustrates the efficiency of the engine
assuming a 10 mA constant load.
The X axis represents the supply voltage. BOOST
mode should be used when voltage ranges from 0.9 V
to 2.0 V to sustain a decent efficiency over 70 %. From
that point on, the power dissipation becomes quite
large.
BUCK mode can operate correctly with voltages in the
range of 2.35 V to 3.3 V.
There are two voltage areas in Figure 10 designated by
dashed lines. The first one (0 V to 0.9 V) indicates that
the DA14580 is not operational when the voltage is
below 0.9 V. This is the absolute threshold for the DC-
DC converter Boost mode.
The second area (1.8 V to 2.2 V) indicates that Deep
Sleep mode is not allowed when the DC-DC converter
is configured in BUCK mode and the voltage is within
this range, because the OTP will not be readable any
more. However, this part of the voltage range can be
covered by the BOOST mode. Furthermore, when
BUCK mode is mandatory, Extended Sleep mode can
be activated instead of Deep Sleep mode, thus not
using the OTP for the code mirroring but retain the
code in SysRAM.
Note: The system should never be cold booted when
the supply voltage is less than 2.5 V. A manual power
up with a power supply less than 2.5 V in buck mode
might create instability.
Figure 9 Supply overview, Alkaline-cell application
Boost Converter
on
LDO
VBAT1V SWITCH
VBAT3V
VDCDC
LDO LDO
digital
0.9 V to 2.0 V
< 0.9 V
analog/RF
retention
Alkaline
or
NiMH
DA14580
internal supply for boost conv.
VDCDC_RF
VBAT_RF
Figure 10 DC-DC efficiency in Buck/Boost mode at
various voltage levels
50%
55%
60%
65%
70%
75%
80%
85%
90%
95%
00.511.522.533.5
DC‐DCEfficiencyvsVoltage
Buck Boost Boost(Vout>1.4V)
1.80.9 2.35
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 17 Final - January 29, 2015 v3.1
4. Registers
This section contains a detailed view of the DA14580 registers. It is organized as follows: An overview table is pre-
sented initially, which depicts all register names, addresses and descriptions. A detailed bit level description of each
register follows.
The register file of the ARM Cortex-M0 can be found in the following documents, available on the ARM website:
Devices Generic User Guide:
DUI0497A_cortex_m0_r0p0_generic_ug.pdf
Technical Reference Manual:
DDI0432C_cortex_m0_r0p0_trm.pdf
These documents contain the register descriptions for the Nested Vectored Interrupt Controller (NVIC), the System
Control Block (SCB) and the System Timer (SysTick).
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 18 Final - January 29, 2015 v3.1
Table 4: Register map
Address Port Description
0x40008000 OTPC_MODE_REG Mode register
0x40008004 OTPC_PCTRL_REG Bit-programming control register
0x40008008 OTPC_STAT_REG Status register
0x4000800C OTPC_AHBADR_REG AHB master start address
0x40008010 OTPC_CELADR_REG Macrocell start address
0x40008014 OTPC_NWORDS_REG Number of words
0x40008018 OTPC_FFPRT_REG Ports access to fifo logic
0x4000801C OTPC_FFRD_REG Latest read data from the OTPC_FFPRT_REG
0x40008400 PATCH_VALID_REG Validity Control Register
0x40008404 PATCH_VALID_SET_REG Validity Set Control Register
0x40008408 PATCH_VALID_RESET_REG Validity Reset Control Register
0x40008410 PATCH_ADDR0_REG Patch entry 0: Address field
0x40008414 PATCH_DATA0_REG Patch entry 0: Data field
0x40008418 PATCH_ADDR1_REG Patch entry 1: Address field
0x4000841C PATCH_DATA1_REG Patch entry 1: Data field
0x40008420 PATCH_ADDR2_REG Patch entry 2: Address field
0x40008424 PATCH_DATA2_REG Patch entry 2: Data field
0x40008428 PATCH_ADDR3_REG Patch entry 3: Address field
0x4000842C PATCH_DATA3_REG Patch entry 3: Data field
0x40008430 PATCH_ADDR4_REG Patch entry 4: Address field
0x40008434 PATCH_DATA4_REG Patch entry 4: Data field
0x40008438 PATCH_ADDR5_REG Patch entry 5: Address field
0x4000843C PATCH_DATA5_REG Patch entry 5: Data field
0x40008440 PATCH_ADDR6_REG Patch entry 6: Address field
0x40008444 PATCH_DATA6_REG Patch entry 6: Data field
0x40008448 PATCH_ADDR7_REG Patch entry 7: Address field
0x4000844C PATCH_DATA7_REG Patch entry 7: Data field
0x50000000 CLK_AMBA_REG HCLK, PCLK, divider and clock gates
0x50000002 CLK_FREQ_TRIM_REG Xtal frequency trimming register
0x50000004 CLK_PER_REG Peripheral divider register
0x50000008 CLK_RADIO_REG Radio PLL control register
0x5000000A CLK_CTRL_REG Clock control register
0x50000010 PMU_CTRL_REG Power Management Unit control register
0x50000012 SYS_CTRL_REG System Control register
0x50000014 SYS_STAT_REG System status register
0x50000016 TRIM_CTRL_REG Control trimming of the XTAL16M
0x50000020 CLK_32K_REG 32 kHz oscillator register
0x50000022 CLK_16M_REG 16 MHz RC-oscillator register
0x50000024 CLK_RCX20K_REG 20 kHz RXC-oscillator control register
0x50000028 BANDGAP_REG Bandgap trimming
0x5000002A ANA_STATUS_REG Status bit of analog (power management) circuits
0x50000100 WKUP_CTRL_REG Control register for the wakeup counter
0x50000102 WKUP_COMPARE_REG Number of events before wakeup interrupt
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 19 Final - January 29, 2015 v3.1
0x50000104 WKUP_RESET_IRQ_REG Reset wakeup interrupt
0x50000106 WKUP_COUNTER_REG Actual number of events of the wakeup counter
0x50000108 WKUP_RESET_CNTR_REG Reset the event counter
0x5000010A WKUP_SELECT_P0_REG Select which inputs from P0 port can trigger wkup
counter
0x5000010C WKUP_SELECT_P1_REG Select which inputs from P1 port can trigger wkup
counter
0x5000010E WKUP_SELECT_P2_REG Select which inputs from P2 port can trigger wkup
counter
0x50000110 WKUP_SELECT_P3_REG Select which inputs from P3 port can trigger wkup
counter
0x50000112 WKUP_POL_P0_REG Select the sensitivity polarity for each P0 input
0x50000114 WKUP_POL_P1_REG Select the sensitivity polarity for each P1 input
0x50000116 WKUP_POL_P2_REG Select the sensitivity polarity for each P2 input
0x50000118 WKUP_POL_P3_REG Select the sensitivity polarity for each P3 input
0x50000200 QDEC_CTRL_REG Quad Decoder control register
0x50000202 QDEC_XCNT_REG Counter value of the X Axis
0x50000204 QDEC_YCNT_REG Counter value of the Y Axis
0x50000206 QDEC_CLOCKDIV_REG Clock divider register
0x50000208 QDEC_CTRL2_REG Quad Decoder control register
0x5000020A QDEC_ZCNT_REG Z_counter
0x50001000 UART_RBR_THR_DLL_REG Receive Buffer Register
0x50001004 UART_IER_DLH_REG Interrupt Enable Register
0x50001008 UART_IIR_FCR_REG Interrupt Identification Register/FIFO Control Register
0x5000100C UART_LCR_REG Line Control Register
0x50001010 UART_MCR_REG Modem Control Register
0x50001014 UART_LSR_REG Line Status Register
0x50001018 UART_MSR_REG Modem Status Register
0x5000101C UART_SCR_REG Scratchpad Register
0x50001020 UART_LPDLL_REG Low Power Divisor Latch Low
0x50001024 UART_LPDLH_REG Low Power Divisor Latch High
0x50001030 UART_SRBR_STHR0_REG Shadow Receive/Transmit Buffer Register
0x50001034 UART_SRBR_STHR1_REG Shadow Receive/Transmit Buffer Register
0x50001038 UART_SRBR_STHR2_REG Shadow Receive/Transmit Buffer Register
0x5000103C UART_SRBR_STHR3_REG Shadow Receive/Transmit Buffer Register
0x50001040 UART_SRBR_STHR4_REG Shadow Receive/Transmit Buffer Register
0x50001044 UART_SRBR_STHR5_REG Shadow Receive/Transmit Buffer Register
0x50001048 UART_SRBR_STHR6_REG Shadow Receive/Transmit Buffer Register
0x5000104C UART_SRBR_STHR7_REG Shadow Receive/Transmit Buffer Register
0x50001050 UART_SRBR_STHR8_REG Shadow Receive/Transmit Buffer Register
0x50001054 UART_SRBR_STHR9_REG Shadow Receive/Transmit Buffer Register
0x50001058 UART_SRBR_STHR10_REG Shadow Receive/Transmit Buffer Register
0x5000105C UART_SRBR_STHR11_REG Shadow Receive/Transmit Buffer Register
0x50001060 UART_SRBR_STHR12_REG Shadow Receive/Transmit Buffer Register
0x50001064 UART_SRBR_STHR13_REG Shadow Receive/Transmit Buffer Register
Table 4: Register map
Address Port Description
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 20 Final - January 29, 2015 v3.1
0x50001068 UART_SRBR_STHR14_REG Shadow Receive/Transmit Buffer Register
0x5000106C UART_SRBR_STHR15_REG Shadow Receive/Transmit Buffer Register
0x5000107C UART_USR_REG UART Status register.
0x50001080 UART_TFL_REG Transmit FIFO Level
0x50001084 UART_RFL_REG Receive FIFO Level.
0x50001088 UART_SRR_REG Software Reset Register.
0x5000108C UART_SRTS_REG Shadow Request to Send
0x50001090 UART_SBCR_REG Shadow Break Control Register
0x50001094 UART_SDMAM_REG Shadow DMA Mode
0x50001098 UART_SFE_REG Shadow FIFO Enable
0x5000109C UART_SRT_REG Shadow RCVR Trigger
0x500010A0 UART_STET_REG Shadow TX Empty Trigger
0x500010A4 UART_HTX_REG Halt TX
0x500010F4 UART_CPR_REG Component Parameter Register
0x500010F8 UART_UCV_REG Component Version
0x500010FC UART_CTR_REG Component Type Register
0x50001100 UART2_RBR_THR_DLL_REG Receive Buffer Register
0x50001104 UART2_IER_DLH_REG Interrupt Enable Register
0x50001108 UART2_IIR_FCR_REG Interrupt Identification Register/FIFO Control Register
0x5000110C UART2_LCR_REG Line Control Register
0x50001110 UART2_MCR_REG Modem Control Register
0x50001114 UART2_LSR_REG Line Status Register
0x50001118 UART2_MSR_REG Modem Status Register
0x5000111C UART2_SCR_REG Scratchpad Register
0x50001120 UART2_LPDLL_REG Low Power Divisor Latch Low
0x50001124 UART2_LPDLH_REG Low Power Divisor Latch High
0x50001130 UART2_SRBR_STHR0_REG Shadow Receive/Transmit Buffer Register
0x50001134 UART2_SRBR_STHR1_REG Shadow Receive/Transmit Buffer Register
0x50001138 UART2_SRBR_STHR2_REG Shadow Receive/Transmit Buffer Register
0x5000113C UART2_SRBR_STHR3_REG Shadow Receive/Transmit Buffer Register
0x50001140 UART2_SRBR_STHR4_REG Shadow Receive/Transmit Buffer Register
0x50001144 UART2_SRBR_STHR5_REG Shadow Receive/Transmit Buffer Register
0x50001148 UART2_SRBR_STHR6_REG Shadow Receive/Transmit Buffer Register
0x5000114C UART2_SRBR_STHR7_REG Shadow Receive/Transmit Buffer Register
0x50001150 UART2_SRBR_STHR8_REG Shadow Receive/Transmit Buffer Register
0x50001154 UART2_SRBR_STHR9_REG Shadow Receive/Transmit Buffer Register
0x50001158 UART2_SRBR_STHR10_REG Shadow Receive/Transmit Buffer Register
0x5000115C UART2_SRBR_STHR11_REG Shadow Receive/Transmit Buffer Register
0x50001160 UART2_SRBR_STHR12_REG Shadow Receive/Transmit Buffer Register
0x50001164 UART2_SRBR_STHR13_REG Shadow Receive/Transmit Buffer Register
0x50001168 UART2_SRBR_STHR14_REG Shadow Receive/Transmit Buffer Register
0x5000116C UART2_SRBR_STHR15_REG Shadow Receive/Transmit Buffer Register
0x5000117C UART2_USR_REG UART Status register.
0x50001180 UART2_TFL_REG Transmit FIFO Level
Table 4: Register map
Address Port Description
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 21 Final - January 29, 2015 v3.1
0x50001184 UART2_RFL_REG Receive FIFO Level.
0x50001188 UART2_SRR_REG Software Reset Register.
0x5000118C UART2_SRTS_REG Shadow Request to Send
0x50001190 UART2_SBCR_REG Shadow Break Control Register
0x50001194 UART2_SDMAM_REG Shadow DMA Mode
0x50001198 UART2_SFE_REG Shadow FIFO Enable
0x5000119C UART2_SRT_REG Shadow RCVR Trigger
0x500011A0 UART2_STET_REG Shadow TX Empty Trigger
0x500011A4 UART2_HTX_REG Halt TX
0x500011F4 UART2_CPR_REG Component Parameter Register
0x500011F8 UART2_UCV_REG Component Version
0x500011FC UART2_CTR_REG Component Type Register
0x50001200 SPI_CTRL_REG SPI control register 0
0x50001202 SPI_RX_TX_REG0 SPI RX/TX register0
0x50001204 SPI_RX_TX_REG1 SPI RX/TX register1
0x50001206 SPI_CLEAR_INT_REG SPI clear interrupt register
0x50001208 SPI_CTRL_REG1 SPI control register 1
0x50001300 I2C_CON_REG I2C Control Register
0x50001304 I2C_TAR_REG I2C Target Address Register
0x50001308 I2C_SAR_REG I2C Slave Address Register
0x50001310 I2C_DATA_CMD_REG I2C Rx/Tx Data Buffer and Command Register
0x50001314 I2C_SS_SCL_HCNT_REG Standard Speed I2C Clock SCL High Count Register
0x50001318 I2C_SS_SCL_LCNT_REG Standard Speed I2C Clock SCL Low Count Register
0x5000131C I2C_FS_SCL_HCNT_REG Fast Speed I2C Clock SCL High Count Register
0x50001320 I2C_FS_SCL_LCNT_REG Fast Speed I2C Clock SCL Low Count Register
0x5000132C I2C_INTR_STAT_REG I2C Interrupt Status Register
0x50001330 I2C_INTR_MASK_REG I2C Interrupt Mask Register
0x50001334 I2C_RAW_INTR_STAT_REG I2C Raw Interrupt Status Register
0x50001338 I2C_RX_TL_REG I2C Receive FIFO Threshold Register
0x5000133C I2C_TX_TL_REG I2C Transmit FIFO Threshold Register
0x50001340 I2C_CLR_INTR_REG Clear Combined and Individual Interrupt Register
0x50001344 I2C_CLR_RX_UNDER_REG Clear RX_UNDER Interrupt Register
0x50001348 I2C_CLR_RX_OVER_REG Clear RX_OVER Interrupt Register
0x5000134C I2C_CLR_TX_OVER_REG Clear TX_OVER Interrupt Register
0x50001350 I2C_CLR_RD_REQ_REG Clear RD_REQ Interrupt Register
0x50001354 I2C_CLR_TX_ABRT_REG Clear TX_ABRT Interrupt Register
0x50001358 I2C_CLR_RX_DONE_REG Clear RX_DONE Interrupt Register
0x5000135C I2C_CLR_ACTIVITY_REG Clear ACTIVITY Interrupt Register
0x50001360 I2C_CLR_STOP_DET_REG Clear STOP_DET Interrupt Register
0x50001364 I2C_CLR_START_DET_REG Clear START_DET Interrupt Register
0x50001368 I2C_CLR_GEN_CALL_REG Clear GEN_CALL Interrupt Register
0x5000136C I2C_ENABLE_REG I2C Enable Register
0x50001370 I2C_STATUS_REG I2C Status Register
0x50001374 I2C_TXFLR_REG I2C Transmit FIFO Level Register
Table 4: Register map
Address Port Description
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 22 Final - January 29, 2015 v3.1
0x50001378 I2C_RXFLR_REG I2C Receive FIFO Level Register
0x5000137C I2C_SDA_HOLD_REG I2C SDA Hold Time Length Register
0x50001380 I2C_TX_ABRT_SOURCE_REG I2C Transmit Abort Source Register
0x50001394 I2C_SDA_SETUP_REG I2C SDA Setup Register
0x50001398 I2C_ACK_GENERAL_CALL_REG I2C ACK General Call Register
0x5000139C I2C_ENABLE_STATUS_REG I2C Enable Status Register
0x500013A0 I2C_IC_FS_SPKLEN_REG I2C SS and FS spike suppression limit Size
0x50001400 GPIO_IRQ0_IN_SEL_REG GPIO interrupt selection for GPIO_IRQ0
0x50001402 GPIO_IRQ1_IN_SEL_REG GPIO interrupt selection for GPIO_IRQ1
0x50001404 GPIO_IRQ2_IN_SEL_REG GPIO interrupt selection for GPIO_IRQ2
0x50001406 GPIO_IRQ3_IN_SEL_REG GPIO interrupt selection for GPIO_IRQ3
0x50001408 GPIO_IRQ4_IN_SEL_REG GPIO interrupt selection for GPIO_IRQ4
0x5000140C GPIO_DEBOUNCE_REG debounce counter value for GPIO inputs
0x5000140E GPIO_RESET_IRQ_REG GPIO interrupt reset register
0x50001410 GPIO_INT_LEVEL_CTRL_REG high or low level select for GPIO interrupts
0x50001412 KBRD_IRQ_IN_SEL0_REG GPIO interrupt selection for KBRD_IRQ for P0
0x50001414 KBRD_IRQ_IN_SEL1_REG GPIO interrupt selection for KBRD_IRQ for P1 and P2
0x50001416 KBRD_IRQ_IN_SEL2_REG GPIO interrupt selection for KBRD_IRQ for P3
0x50001500 GP_ADC_CTRL_REG General Purpose ADC Control Register
0x50001502 GP_ADC_CTRL2_REG General Purpose ADC Second Control Register
0x50001504 GP_ADC_OFFP_REG General Purpose ADC Positive Offset Register
0x50001506 GP_ADC_OFFN_REG General Purpose ADC Negative Offset Register
0x50001508 GP_ADC_CLEAR_INT_REG General Purpose ADC Clear Interrupt Register
0x5000150A GP_ADC_RESULT_REG General Purpose ADC Result Register
0x5000150C GP_ADC_DELAY_REG General Purpose ADC Delay Register
0x5000150E GP_ADC_DELAY2_REG General Purpose ADC Second Delay Register
0x50001600 CLK_REF_SEL_REG Select clock for oscillator calibration
0x50001602 CLK_REF_CNT_REG Count value for oscillator calibration
0x50001604 CLK_REF_VAL_L_REG XTAL16M reference cycles, lower 16 bits
0x50001606 CLK_REF_VAL_H_REG XTAL16M reference cycles, upper 16 bits
0x50003000 P0_DATA_REG P0 Data input / output register
0x50003002 P0_SET_DATA_REG P0 Set port pins register
0x50003004 P0_RESET_DATA_REG P0 Reset port pins register
0x50003006 P00_MODE_REG P00 Mode Register
0x50003008 P01_MODE_REG P01 Mode Register
0x5000300A P02_MODE_REG P02 Mode Register
0x5000300C P03_MODE_REG P03 Mode Register
0x5000300E P04_MODE_REG P04 Mode Register
0x50003010 P05_MODE_REG P05 Mode Register
0x50003012 P06_MODE_REG P06 Mode Register
0x50003014 P07_MODE_REG P07 Mode Register
0x50003020 P1_DATA_REG P1 Data input / output register
0x50003022 P1_SET_DATA_REG P1 Set port pins register
0x50003024 P1_RESET_DATA_REG P1 Reset port pins register
Table 4: Register map
Address Port Description
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 23 Final - January 29, 2015 v3.1
0x50003026 P10_MODE_REG P10 Mode Register
0x50003028 P11_MODE_REG P11 Mode Register
0x5000302A P12_MODE_REG P12 Mode Register
0x5000302C P13_MODE_REG P13 Mode Register
0x5000302E P14_MODE_REG P14 Mode Register
0x50003030 P15_MODE_REG P15 Mode Register
0x50003040 P2_DATA_REG P2 Data input / output register
0x50003042 P2_SET_DATA_REG P2 Set port pins register
0x50003044 P2_RESET_DATA_REG P2 Reset port pins register
0x50003046 P20_MODE_REG P20 Mode Register
0x50003048 P21_MODE_REG P21 Mode Register
0x5000304A P22_MODE_REG P22 Mode Register
0x5000304C P23_MODE_REG P23 Mode Register
0x5000304E P24_MODE_REG P24 Mode Register
0x50003050 P25_MODE_REG P25 Mode Register
0x50003052 P26_MODE_REG P26 Mode Register
0x50003054 P27_MODE_REG P27 Mode Register
0x50003056 P28_MODE_REG P28 Mode Register
0x50003058 P29_MODE_REG P29 Mode Register
0x50003070 P01_PADPWR_CTRL_REG Ports 0 and 1 Output Power Control Register
0x50003072 P2_PADPWR_CTRL_REG Port 2 Output Power Control Register
0x50003074 P3_PADPWR_CTRL_REG Port 3 Output Power Control Register
0x50003080 P3_DATA_REG P3 Data input / output register
0x50003082 P3_SET_DATA_REG P3 Set port pins register
0x50003084 P3_RESET_DATA_REG P3 Reset port pins register
0x50003086 P30_MODE_REG P30 Mode Register
0x50003088 P31_MODE_REG P31 Mode Register
0x5000308A P32_MODE_REG P32 Mode Register
0x5000308C P33_MODE_REG P33 Mode Register
0x5000308E P34_MODE_REG P34 Mode Register
0x50003090 P35_MODE_REG P35 Mode Register
0x50003092 P36_MODE_REG P36 Mode Register
0x50003094 P37_MODE_REG P37 Mode Register
0x50003100 WATCHDOG_REG Watchdog timer register.
0x50003102 WATCHDOG_CTRL_REG Watchdog control register.
0x50003200 CHIP_ID1_REG Chip identification register 1.
0x50003201 CHIP_ID2_REG Chip identification register 2.
0x50003202 CHIP_ID3_REG Chip identification register 3.
0x50003203 CHIP_SWC_REG Software compatibility register.
0x50003204 CHIP_REVISION_REG Chip revision register.
0x50003205 CHIP_CONFIG1_REG Chip configuration register 1.
0x50003206 CHIP_CONFIG2_REG Chip configuration register 2.
0x50003207 CHIP_CONFIG3_REG Chip configuration register 3.
0x5000320A CHIP_TEST1_REG Chip test register 1.
Table 4: Register map
Address Port Description
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 24 Final - January 29, 2015 v3.1
0x5000320B CHIP_TEST2_REG Chip test register 2.
0x50003300 SET_FREEZE_REG Controls freezing of various timers/counters.
0x50003302 RESET_FREEZE_REG Controls unfreezing of various timers/counters.
0x50003304 DEBUG_REG Various debug information register.
0x50003306 GP_STATUS_REG General purpose system status register.
0x50003308 GP_CONTROL_REG General purpose system control register.
0x50003400 TIMER0_CTRL_REG Timer0 control register
0x50003402 TIMER0_ON_REG Timer0 on control register
0x50003404 TIMER0_RELOAD_M_REG 16 bits reload value for Timer0
0x50003406 TIMER0_RELOAD_N_REG 16 bits reload value for Timer0
0x50003408 PWM2_DUTY_CYCLE Duty Cycle for PWM2
0x5000340A PWM3_DUTY_CYCLE Duty Cycle for PWM3
0x5000340C PWM4_DUTY_CYCLE Duty Cycle for PWM4
0x5000340E TRIPLE_PWM_FREQUENCY Frequency for PWM 2,3 and 4
0x50003410 TRIPLE_PWM_CTRL_REG PWM 2 3 4 Control
Table 4: Register map
Address Port Description
Table 5: OTPC_MODE_REG (0x40008000)
Bit Mode Symbol Description Reset
31:30 --Reserved 0x0
29:28 R/W OTPC_MODE_PRG_
PORT_MUX
Selects the source that is connected to the prg_port port of
the controller.
00 - {16'd0, BANDGAP_REG[15:0]}
01 - {RF_RSSI_COMP_CTRL_REG[15:0], 8'd0,
RFIO_CTRL1_REG{7:0]}
10 - {3'd0, RF_LNA_CTRL3_REG[4:0],
RF_LNA_CTRL2_REG[11:0], RF_LNA_CTRL1_REG[11:0]}
11 - {28'd0, RF_VCO_CTRL_REG[3:0]}
See OTPC_MODE_PRG_PORT_SEL about the use of the
prg_port
0x0
27:9 --Reserved 0x0
8R/W OPTC_MODE_PRG_
FAST
Defines the timing that will be used for all the programming
activities (APROG, MPROG and TWR)
0 - Selects the normal timing
1 - Selects the fast timing
0
7R/W OTPC_MODE_PRG_
PORT_SEL
Selects an alternative data source for the programming of the
OTP macrocells, when the controller is configured in APROG
mode.
0 - The fifo will be used as the data source. The fifo will be
filled with a way defined by the register
OTPC_MODE_USE_DMA. The number of words that will be
programmed is defined by OTPC_NWORDS.
1 - Only one word will programmed. The value of the word is
contained in the prg_port port of the controller. The values of
the registers OTPC_MODE_USE_DMA, OTPC_NWORDS
and the contents of the FIFO will not be used.
0x0
6R/W OTPC_MODE_TWO_
CC_ACC
Defines the duration of each read from the OTP macrocells.
0 - Reads 16 bits of data every one clock cycle.
1 - Reads 16 bits of data every two clock cycles.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 25 Final - January 29, 2015 v3.1
5R/W OTPC_MODE_FIFO_
FLUSH
Writing 1, removes any content from the FIFO. This bit returns
automatically to 0.
0x0
4R/W OTPC_MODE_USE_
DMA
Selects the use of the dma, when the controller is configured
in one of the modes: AREAD or APROG.
0 - DMAis not used. The data should be transfered from/to
controller through OTPC_FFPRT_REG
1 - DMA is used. Data transfers from/to controller are per-
formed automatically. The AHB base address should be con-
figured in OTPC_AHBADR_REG before the selection of the
mode.
If programming of the OTPC_MODE_REG is performed
through the serial interface,the OTPC_MODE_USE_DMA will
be set to 0 automatically.
If the controller is in APROG mode and the
OTPC_MODE_PRG_PORT_SEL is enabled, the dma will
stay inactive.
0x0
3--Reserved 0x0
2:0 R/W OTPC_MODE_MODE Defines the mode of operation of the OTPC controller. The
encoding of the modes is as follows:
000 - STBY mode
001 - MREAD mode
010 - MPROG mode
011 - AREAD mode
100 - APROG mode
101 - Test mode. Reserved
110 - Test mode. Reserved
111 - Test mode. Reserved
To manually move between modes, always return to STBY
mode first.
0x0
Table 5: OTPC_MODE_REG (0x40008000)
Bit Mode Symbol Description Reset
Table 6: OTPC_PCTRL_REG (0x40008004)
Bit Mode Symbol Description Reset
31:28 --Reserved 0x0
27 R/W OTPC_PCTRL_ENU Enables the programming in the upper bank of the OTP.
0 - Programming sequence is not applied in the upper bank.
1 - Programming sequence is applied in the upper bank.
0x0
26 R/W OTPC_PCTRL_BITU Defines the value of the selected bit in the upper bank, after
the programming sequence.
0x0
25 R/W OTPC_PCTRL_ENL Enables the programming in the lower bank.
0 - The programming sequence is not applied in the lower
bank.
1 -The programming sequence is applied in the lower bank.
0x0
24 R/W OTPC_PCTRL_BITL Defines the value of the selected bit in the lower bank, after
the programming sequence.
0x0
23 R/W OTPC_PCTRL_BSEL
U
Selects between the U1 and U0 byte for the programming
sequence in the upper bank.
0 - Program the U0 byte
1 - Program the U1 byte
0x0
22:20 R/W OTPC_PCTRL_BADR
U
Selects the bit inside the Ux (x=0,1) byte, which will be pro-
grammed in the upper bank.
0x0
19 R/W OTPC_PCTRL_BSEL
L
Selects between the L1 and L0 byte for the programming
sequence in the lower bank.
0 - Program the L0 byte
1 - Program the L1 byte
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 26 Final - January 29, 2015 v3.1
18:16 R/W OTPC_PCTRL_BADR
L
Selects the bit inside the Lx (x=0,1) byte, which will be pro-
grammed in the lower bank.
0x0
15:13 --Reserved 0x0
12:0 R/W OTPC_PCTRL_WAD
DR
Defines the address of a 32 bits word {U1,L1,U0,L0} in the
macrocells, where one or two bits will be programmed. There
are two macrocell banks, with 8 bits each. Each bank contrib-
ute with two memory positions for each 32 bits word. The Ux,
Lx represent the bytes of the upper and lower bank respec-
tively.
0x0
Table 6: OTPC_PCTRL_REG (0x40008004)
Bit Mode Symbol Description Reset
Table 7: OTPC_STAT_REG (0x40008008)
Bit Mode Symbol Description Reset
31:29 --Reserved 0x0
28:16 ROTPC_STAT_NWOR
DS
Contains the current value of the words to be processed. 0
15 ROTPC_STAT_TERR_
U
Indicates the upper bank as the source of a test error. This
value is valid when OTPC_STAT_TERROR is valid.
0 - There is no test error in the upper bank
1 - A test error has occured in the upper bank
0x0
14 ROTPC_STAT_TERR_L Indicates the lower bank as the source of a test error. The
value is valid when OTPC_STAT_TERROR is valid.
0 - There is no test error in the lower bank
1 - A test error has occured in the lower bank
0x0
13 ROTPC_STAT_PERR_
U
Indicates the upper bank as the source of a programming
error. The value is valid when OTPC_STAT_PERROR is
valid.
0 - There is no programming error in the upper bank
1 - A programming error has occured in the upper bank
0x0
12 ROTPC_STAT_PERR_
L
Indicates the lower bank as the source of a programming
error. The value is valid when OTPC_STAT_PERROR is
valid.
0 - There is no programming error in the lower bank
1 - A programming error has occured in the lower bank
0x0
11:8 ROTPC_STAT_FWORD
S
Indicates the number of words which contained in the fifo of
the controller.
0x0
7:5 --Reserved 0x0
4ROTPC_STAT_ARDY Monitors the progress of read or programming operations
while in the AREAD or APROG modes.
0 - The controller is busy while reading or programming
(AREAD or APROG modes).
1 - The controller is not busy in AREAD or APROG mode.
0x1
3ROTPC_STAT_TERRO
R
Indicates the result of a test sequence. Should be checked
after the end of a TBLANK, TDEC and TWR mode
(OTPC_STAT_TRDY= 1).
0 - The test sequence ends with no error.
1 - The test sequence has failed.
0x0
2ROTPC_STAT_TRDY Indicates the state of a test mode. Should be used to monitor
the progress of the TBLANK, TDEC and TWR modes.
0 - The controller is busy. A test mode is in progress.
1 - There is no active test mode.
0x1
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 27 Final - January 29, 2015 v3.1
1ROTPC_STAT_PERRO
R
Indicates that an error has occurred during the bit-program-
ming process.
0 - No error during the bit-programming process.
1 - The process of bit-programming failed.
When the controller is in MPROG mode, this bit should be
checked after the end of the programming process
(OTPC_STAT_PRDY= 1).
During APROG mode, the value of this field is normal to
change periodically. Upon finishing the operation in the
APROG mode (OTPC_STAT_ARDY= 1), this field indicates if
the programming has failed or ended succesfully.
0x0
0ROTPC_STAT_PRDY Indicates the state of a bit-programming process.
0 - The controller is busy. A bit-programming is in progress
1 - The logic which performs bit-programming is idle.
When the controller is in MPROG mode, this bit should be
used to monitor the progress of a programming request.
During APROG mode, the value of this field it is normal to
changing periodically.
0x1
Table 7: OTPC_STAT_REG (0x40008008)
Bit Mode Symbol Description Reset
Table 8: OTPC_AHBADR_REG (0x4000800C)
Bit Mode Symbol Description Reset
31:2 R/W OTPC_AHBADR Tthe AHB address used by the AHB master interface of the
controller (
bits [31:2]).
0x0
1:0 --Reserved 0x0
Table 9: OTPC_CELADR_REG (0x40008010)
Bit Mode Symbol Description Reset
31:13 --Reserved 0x0
12:0 R/W OTPC_CELADR Defines a word address inside the macrocell. Used in modes
AREAD and APROG and is automatically updated.
0x0
Table 10: OTPC_NWORDS_REG (0x40008014)
Bit Mode Symbol Description Reset
31:13 --Reserved 0x0
12:0 R/W OTPC_NWORDS The number of words (minus one) for reading/programming
during the AREAD/APROG mode.
If in APROG mode, and the OTPC_MODE_PRG_PORT_SEL
is enabled (=1), this register will not be used and will stay
unchanged.
During mirroring, this register reflects the current amount of
data that will be copied. It keeps its value until be written by
the software with a new value. The number of the words that
remaining to be processed by the controller is contained in
the field OTPC_STAT_NWORDS.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 28 Final - January 29, 2015 v3.1
Table 11: OTPC_FFPRT_REG (0x40008018)
Bit Mode Symbol Description Reset
31:0 R/W OTPC_FFPRT Provides access to the fifo through an access port. Write this
register with the corresponding data, when the APROG mode
is selected and the DMA is disabled. Read from this register
the corresponding data, when the AREAD mode is selected
and the DMA is disabled.
Check OTPC_STAT_FWORDS register for data/space availa-
bility, before accessing the fifo.
0x0
Table 12: OTPC_FFRD_REG (0x4000801C)
Bit Mode Symbol Description Reset
31:0 ROTPC_FFRD Contains the value read from the fifo, after a read of the
OTPC_FFPRT_REG register.
0x0
Table 13: PATCH_VALID_REG (0x40008400)
Bit Mode Symbol Description Reset
31:8 --Reserved 0x0
7:0 R/W PATCH_VALID Indicates which patch entry is valid. For example, when bit 0
is high it indicates that entry 0 is valid, i.e. the values of
PATCH_ADDR0_REG / PATCH_DATA0_REG, are effective.
0x0
Table 14: PATCH_VALID_SET_REG (0x40008404)
Bit Mode Symbol Description Reset
31:8 --Reserved 0x0
7:0 R/W PATCH_VALID_SET Writing a bit with 1 will set the corresponding bit of
PATCH_VALID_REG to 1. Writing a bit with 0 is ignored.
Read always as 0.
0x0
Table 15: PATCH_VALID_RESET_REG (0x40008408)
Bit Mode Symbol Description Reset
31:8 --Reserved 0x0
7:0 R/W PATCH_VALID_RESE
T
Writing a bit with 1 will clear the corresponding bit of
PATCH_VALID_REG to 0. Writing a bit with zero is ignored.
Read always as 0.
0x0
Table 16: PATCH_ADDR0_REG (0x40008410)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_ADDR This is the value which will be compared to the address on the
AHB. If a match occurs, the data bus willl be filled with the
value in the respective PATCH_DATAx_REG. Bits [1:0] are
read-only and always read as "0".
Never use the base address 0x0 for values in
PATCH_ADDRx_REG because HW Patch block is located
after the Address Remapping block.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 29 Final - January 29, 2015 v3.1
Table 17: PATCH_DATA0_REG (0x40008414)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_DATA This is the value which will be injected into the data bus if
there is a match on the comparison of the address with the
respective PATCH_ADDRx_REG
0x0
Table 18: PATCH_ADDR1_REG (0x40008418)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_ADDR This is the value which will be compared to the address on the
AHB. If a match occurs, the data bus willl be filled with the
value in the respective PATCH_DATAx_REG. Bits [1:0] are
read-only and always read as "0".
Never use the base address 0x0 for values in
PATCH_ADDRx_REG because HW Patch block is located
after the Address Remapping block.
0x0
Table 19: PATCH_DATA1_REG (0x4000841C)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_DATA This is the value which will be injected into the data bus if
there is a match on the comparison of the address with the
respective PATCH_ADDRx_REG
0x0
Table 20: PATCH_ADDR2_REG (0x40008420)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_ADDR This is the value which will be compared to the address on the
AHB. If a match occurs, the data bus willl be filled with the
value in the respective PATCH_DATAx_REG. Bits [1:0] are
read-only and always read as "0".
Never use the base address 0x0 for values in
PATCH_ADDRx_REG because HW Patch block is located
after the Address Remapping block.
0x0
Table 21: PATCH_DATA2_REG (0x40008424)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_DATA This is the value which will be injected into the data bus if
there is a match on the comparison of the address with the
respective PATCH_ADDRx_REG
0x0
Table 22: PATCH_ADDR3_REG (0x40008428)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_ADDR This is the value which will be compared to the address on the
AHB. If a match occurs, the data bus willl be filled with the
value in the respective PATCH_DATAx_REG. Bits [1:0] are
read-only and always read as "0".
Never use the base address 0x0 for values in
PATCH_ADDRx_REG because HW Patch block is located
after the Address Remapping block.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 30 Final - January 29, 2015 v3.1
Table 23: PATCH_DATA3_REG (0x4000842C)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_DATA This is the value which will be injected into the data bus if
there is a match on the comparison of the address with the
respective PATCH_ADDRx_REG
0x0
Table 24: PATCH_ADDR4_REG (0x40008430)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_ADDR This is the value which will be compared to the address on the
AHB. If a match occurs, the data bus willl be filled with the
value in the respective PATCH_DATAx_REG. Bits [1:0] are
read-only and always read as "0".
Never use the base address 0x0 for values in
PATCH_ADDRx_REG because HW Patch block is located
after the Address Remapping block.
0x0
Table 25: PATCH_DATA4_REG (0x40008434)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_DATA This is the value which will be injected into the data bus if
there is a match on the comparison of the address with the
respective PATCH_ADDRx_REG
0x0
Table 26: PATCH_ADDR5_REG (0x40008438)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_ADDR This is the value which will be compared to the address on the
AHB. If a match occurs, the data bus willl be filled with the
value in the respective PATCH_DATAx_REG. Bits [1:0] are
read-only and always read as "0".
Never use the base address 0x0 for values in
PATCH_ADDRx_REG because HW Patch block is located
after the Address Remapping block.
0x0
Table 27: PATCH_DATA5_REG (0x4000843C)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_DATA This is the value which will be injected into the data bus if
there is a match on the comparison of the address with the
respective PATCH_ADDRx_REG
0x0
Table 28: PATCH_ADDR6_REG (0x40008440)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_ADDR This is the value which will be compared to the address on the
AHB. If a match occurs, the data bus willl be filled with the
value in the respective PATCH_DATAx_REG. Bits [1:0] are
read-only and always read as "0".
Never use the base address 0x0 for values in
PATCH_ADDRx_REG because HW Patch block is located
after the Address Remapping block.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 31 Final - January 29, 2015 v3.1
Table 29: PATCH_DATA6_REG (0x40008444)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_DATA This is the value which will be injected into the data bus if
there is a match on the comparison of the address with the
respective PATCH_ADDRx_REG
0x0
Table 30: PATCH_ADDR7_REG (0x40008448)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_ADDR This is the value which will be compared to the address on the
AHB. If a match occurs, the data bus willl be filled with the
value in the respective PATCH_DATAx_REG. Bits [1:0] are
read-only and always read as "0".
Never use the base address 0x0 for values in
PATCH_ADDRx_REG because HW Patch block is located
after the Address Remapping block.
0x0
Table 31: PATCH_DATA7_REG (0x4000844C)
Bit Mode Symbol Description Reset
31:0 R/W PATCH_DATA This is the value which will be injected into the data bus if
there is a match on the comparison of the address with the
respective PATCH_ADDRx_REG
0x0
Table 32: CLK_AMBA_REG (0x50000000)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7R/W OTP_ENABLE Clock enable for OTP controller 0x0
6--Reserved 0x0
5:4 R/W PCLK_DIV APB interface clock (PCLK). Divider is cascaded with
HCLK_DIV. PCLK is HCLK divided by:
0x0: divide by 1
0x1: divide by 2
0x2: divide by 4
0x3: divide by 8
0x2
3:2 --Reserved 0x0
1:0 R/W HCLK_DIV AHB interface and microprocessor clock (HCLK). HCLK is
source clock divided by:
0x0: divide by 1
0x1: divide by 2
0x2: divide by 4
0x3: divide by 8
0x2
Table 33: CLK_FREQ_TRIM_REG (0x50000002)
Bit Mode Symbol Description Reset
15:11 --Reserved 0x0
10:8 R/W COARSE_ADJ Xtal frequency course trimming register.
0x0: lowest frequency
0x7: highest frequencyIncrement or decrement the binary
value with 1. Wait approximately 200 us to allow the adjust-
ment to settle.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 32 Final - January 29, 2015 v3.1
7:0 R/W FINE_ADJ Xtal frequency fine trimming register.
0x00: lowest frequency
0xFF: highest frequency
0x0
Table 33: CLK_FREQ_TRIM_REG (0x50000002)
Bit Mode Symbol Description Reset
Table 34: CLK_PER_REG (0x50000004)
Bit Mode Symbol Description Reset
15 R/W QUAD_ENABLE Enable the Quadrature clock 0x0
14:13 --Reserved 0x0
11 R/W SPI_ENABLE Enable SPI clock 0x0
10 --Reserved 0x0
9:8 R/W SPI_DIV Division factor for SPI
0x0: divide by 1
0x1: divide by 2
0x2: divide by 4
0x3: divide by 8
0x0
7R/W UART1_ENABLE Enable UART1 clock 0x0
6R/W UART2_ENABLE Enable UART2 clock 0x0
5R/W I2C_ENABLE Enable I2C clock 0x0
4R/W WAKEUPCT_ENABLE Enable Wakeup CaptureTimer clock 0x0
3R/W TMR_ENABLE Enable TIMER0 and TIMER2 clock 0x0
2--Reserved 0x0
1:0 R/W TMR_DIV Division factor for TIMER0
0x0: divide by 1
0x1: divide by 2
0x2: divide by 4
0x3: divide by 8
0x0
Table 35: CLK_RADIO_REG (0x50000008)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7R/W BLE_ENABLE Enable the BLE core clocks 0x0
6R/W BLE_LP_RESET Reset for the BLE LP timer 0x1
5:4 R/W BLE_DIV Division factor for BLE core blocks
0x0: divide by 1
0x1: divide by 2
0x2: divide by 4
0x3: divide by 8
The programmed frequency should not be lower than 8 MHz
and not faster than the programmed CPU clock frequency.
Refer also to BLE_CNTL2_REG[BLE_CLK_SEL].
0x0
3R/W RFCU_ENABLE Enable the RF control Unit clock 0x0
2--Reserved 0x0
1:0 R/W RFCU_DIV Division factor for RF Control Unit
0x0: divide by 1
0x1: divide by 2
0x2: divide by 4
0x3: divide by 8
The programmed frequency must be exactly 8 MHz.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 33 Final - January 29, 2015 v3.1
Table 36: CLK_CTRL_REG (0x5000000A)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7RRUNNING_AT_XTAL1
6M
Indicates that the XTAL16M clock is used as clock, and may
not be switched off
0x1
6RRUNNING_AT_RC16
M
Indicates that the RC16M clock is used as clock 0x0
5RRUNNING_AT_32K Indicates that either the RC32k or XTAL32k is being used as
clock
0x0
4--Reserved 0x0
3R/W XTAL16M_SPIKE_FLT
_DISABLE
Disable spikefilter in digital clock 0x0
2R/W XTAL16M_DISABLE Setting this bit instantaneously disables the 16 MHz crystal
oscillator. Also, after sleep/wakeup cycle, the oscillator will not
be enabled. This bit may not be set to '1'when
"RUNNING_AT_XTAL16M is '1' to prevent deadlock. After
resetting this bit, wait for XTAL16_SETTLED or
XTAL16_TRIM_READY to become '1' before switching to
XTAL16 clock source.
0x0
1:0 R/W SYS_CLK_SEL Selects the clock source.
0x0: XTAL16M (check the XTAL16_SETTLED and
XTAL16_TRIM_READY bits!!)
0x1: RC16M
0x2/0x3: either RC32k or XTAL32k is used
0x0
Table 37: PMU_CTRL_REG (0x50000010)
Bit Mode Symbol Description Reset
15:12 --Reserved 0x0
11:8 R/W RETENTION_MODE Select the retainability of the 4 retention RAM macros.
'1' is retainable, '0' is power gated.
(3) is RETRAM4
(2) is RETRAM3
(1) is RETRAM2
(0) is RETRAM1
0x0
7R/W FORCE_BOOST Force the DCDC into boost mode at next wakeup.
Setting this bit reduces the deepsleep current.
FORCE_BOOST has highest priority.
When either FORCE_BOOST or FORCE_BUCK have been
written, these bits cannot be changed.
0x0
6R/W FORCE_BUCK Force the DCDC into buck mode at next wakeup.
Setting this bit reduces the deepsleep current.
FORCE_BOOST has highest priority.
When either FORCE_BOOST or FORCE_BUCK have been
written, these bits cannot be changed.
0x0
5:4 R/W OTP_COPY_DIV Sets the HCLK division during OTP mirroring 0x0
2R/W RADIO_SLEEP Put the digital part of the radio in powerdown 0x1
1R/W PERIPH_SLEEP Put all peripherals (I2C, UART, SPI, ADC) in powerdown 0x1
0R/W RESET_ON_WAKEU
P
Perform a Hardware Reset after waking up. Booter will be
started.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 34 Final - January 29, 2015 v3.1
Table 38: SYS_CTRL_REG (0x50000012)
Bit Mode Symbol Description Reset
15 WSW_RESET Writing a '1' to this bit will reset the device, except for:
SYS_CTRL_REG
CLK_FREQ_TRIM_REG
...
0x0
9R/W TIMEOUT_DISABLE Disables timeout in Power statemachine. By default, the
statemachine continues if after 2 ms the blocks are not
started up. This can be read back from
ANA_STATUS_REG.
0x0
8--Reserved 0x0
7R/W DEBUGGER_ENABL
E
Enable the debugger. This bit is set by the booter according to
the OTP header. If not set, the SWDIO and SW_CLK can be
used as gpio ports.
0x0
6R/W OTPC_RESET_REQ Reset request for the OTP controller. 0x0
5R/W PAD_LATCH_EN Latches the control signals of the pads for state retention in
powerdown mode.
0: Control signals are retained
1: Latch is transparant, pad can be recontrolled
0x1
4R/W OTP_COPY Enables OTP to SysRAM copy action after waking up
PD_SYS
0x0
3R/W CLK32_SOURCE Sets the clock source of the 32 kHz clock
0 = RC-oscillator
1 = 32 kHz crystal oscillator
0x0
2R/W RET_SYSRAM Sets the development phase mode.
The PD_SYS is not actually power gated (SysRAM is
retained).
No copy action to SysRAM is done when the system wakes
up.
For emulating startup time, the OTP_COPY bit still needs to
be set.
0x0
1:0 R/W REMAP_ADR0 Controls which memory is located at address 0x0000 for exe-
cution.
0x0: ROM
0x1: OTP
0x2: SysRAM
0x3: RetRAM
0x0
Table 39: SYS_STAT_REG (0x50000014)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7RXTAL16_SETTLED Indicates that XTAL16 has had > 2 ms of settle time 0x0
6RXTAL16_TRIM_READ
Y
Indicates that XTAL trimming mechanism is ready, i.e. the
trimming equals CLK_FREQ_TRIM_REG.
0x1
5RDBG_IS_UP Indicates that PD_DBG is functional 0x0
4RDBG_IS_DOWN Indicates that PD_DBG is in power down 0x1
3RPER_IS_UP Indicates that PD_PER is functional 0x0
2RPER_IS_DOWN Indicates that PD_PER is in power down 0x1
1RRAD_IS_UP Indicates that PD_RAD is functional 0x0
0RRAD_IS_DOWN Indicates that PD_RAD is in power down 0x1
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 35 Final - January 29, 2015 v3.1
Note 1: The period duration of 250 us is derived by dividing the RC16M clock signal by 4000. Consequently, the period duration may vary over tem-
perature.
Table 40: TRIM_CTRL_REG (0x50000016)
Bit Mode Symbol Description Reset
7:4 R/W TRIM_TIME Defines the delay between XTAL16M enable and applying the
CLK_FREQ_TRIM_REG in steps of 250 us.
0x0: apply directly
0x1: wait between 0 and 250 us
0x2: wait between 250 us and 500 us
etc.
(Note 1)
0xA
3:0 R/W SETTLE_TIME Defines the delay between applying CLK_FREQ_TRIM_REG
and XTAL16_SETTLED in steps of 250 us.
0x0: XTAL16_SETTLED is set direcly
0x1: wait between 0 and 250 us
0x2: wait between 250 us and 500 us
etc.
0x2
Table 41: CLK_32K_REG (0x50000020)
Bit Mode Symbol Description Reset
15:13 --Reserved 0x0
12 R/W XTAL32K_DISABLE_
AMPREG
Setting this bit disables the amplitude regulation of the
XTAL32kHz oscillator.
Set this bit to '1' for an external clock applied at XTAL32Kp.
Keep this bit '0' with a crystal between XTAL32Kp and
XTAL32Km.
0x0
11:8 R/W RC32K_TRIM Controls the frequency of the RC32K oscillator.
0x0: lowest frequency
0x7: default
0xF: highest frequency
0x7
7R/W RC32K_ENABLE Enables the 32 kHz RC oscillator 0x1
6:3 R/W XTAL32K_CUR Bias current for the 32kHz XTAL oscillator.
0x0: minimum
0x3: default
0xF: maximum
For each application there is an optimal setting for which the
startup behaviour is optimal.
0x3
2:1 R/W XTAL32K_RBIAS Setting for the bias resistor of the 32 kHz XTAL oscillator.
0x0: maximum
0x3: minimum
Prefered setting will be provided by Dialog.
0x2
0R/W XTAL32K_ENABLE Enables the 32 kHz XTAL oscillator 0x0
Table 42: CLK_16M_REG (0x50000022)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9R/W XTAL16_NOISE_FILT
_ENABLE
Enables noise flter in 16 MHz crystal oscillator 0x0
8R/W XTAL16_BIAS_SH_E
NABLE
Enables Ibias sample/hold function in 16 MHz crystal oscilla-
tor. This bit should be set when the system wake up and reset
before entering deep or extended sleep mode.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 36 Final - January 29, 2015 v3.1
Note 2: 0xF is the lowest voltage, but is too low for reliable startup at high temperature in combination with extended sleep. 0xA is 100 mV higher
and considered to be the lowest value which is safe to use. 0x0 or 0x1 is again 100 mV higher and 0x0 is the reset value. 0x4 is the maxi-
mum voltage.
7:5 R/W XTAL16_CUR_SET Bias current for the 16 MHz XTAL oscillator.
0x0: minimum
0x7: maximum
0x5
4:1 R/W RC16M_TRIM Controls the frequency of the RC16M oscillator.
0x0: lowest frequency
0xF: highest frequency
0x0
0R/W RC16M_ENABLE Enables the 16 MHz RC oscillator 0x0
Table 42: CLK_16M_REG (0x50000022)
Bit Mode Symbol Description Reset
Table 43: CLK_RCX20K_REG (0x50000024)
Bit Mode Symbol Description Reset
12 R/W RCX20K_SELECT Selects RCX oscillator.
0 : RC32K oscillator
1: RCX oscillator
0
11 R/W RCX20K_ENABLE Enable the RCX oscillator 0
10 R/W RCX20K_LOWF Extra low frequency 0
9:8 R/W RCX20K_BIAS Bias control 1
7:4 R/W RCX20K_NTC Temperature control 7
3:0 R/W RCX20K_TRIM Controls the frequency of the RCX oscillator.
0x0: lowest frequency
0x7: default
0xF: highest frequency
8
Table 44: BANDGAP_REG (0x50000028)
Bit Mode Symbol Description Reset
15 --Reserved 0x0
14 R/W BGR_LOWPOWER Test-mode, do not use.
It disables the bandgap core (voltages will continue for some
time, but will slowely drift away)
0x0
13:10 R/W LDO_RET_TRIM (Note 2) 0x0
9:5 R/W BGR_ITRIM Current trimming for bias 0x0
4:0 R/W BGR_TRIM Trim register for bandgap 0x0
Table 45: ANA_STATUS_REG (0x5000002A)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9RBOOST_SELECTED Indicates that DCDC is in boost mode 0x0
8--Reserved 0x0
7RBANDGAP_OK Indicates that BANDGAP is OK 0x1
6RBOOST_VBAT_OK Indicates that VBAT is above threshold while in BOOST con-
verter mode.
0x0
5RLDO_ANA_OK Indicates that LDO_ANA is in regulation. This LDO is used for
the general-purpose ADC only
0x0
4RLDO_VDD_OK Indicates that LDO_VDD is in regulation 0x1
3RLDO_OTP_OK Indicates that LDO_OTP is in regulation 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 37 Final - January 29, 2015 v3.1
2RVDCDC_OK Indicates that VDCDC is above threshold. 0x0
1RVBAT1V_OK Indicates that VBAT1V is above threshold. 0x0
0RVBAT1V_AVAILABLE Indicates that VBAT1V is available. 0x0
Table 45: ANA_STATUS_REG (0x5000002A)
Bit Mode Symbol Description Reset
Table 46: WKUP_CTRL_REG (0x50000100)
Bit Mode Symbol Description Reset
15:14 --Reserved 0x0
7R/W WKUP_ENABLE_IRQ 0: no interrupt will be enabled
1: if the event counter reaches the value set by
WKUP_COMPARE_REG an IRQ will be generated
0x0
6R/W WKUP_SFT_KEYHIT 0: no effect
1: emulate key hit. The event counter will increment by 1
(after debouncing if enabled). First make this bit 0 before any
new key hit can be sensed.
0x0
5:0 R/W WKUP_DEB_VALUE Keyboard debounce time (N*1 ms with N = 1 to 63).
0x0: no debouncing
0x1 to 0x3F: 1 ms to 63 ms debounce time
0x0
Table 47: WKUP_COMPARE_REG (0x50000102)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W COMPARE The number of events that have to be counted before the
wakeup interrupt will be given
0x0
Table 48: WKUP_RESET_IRQ_REG (0x50000104)
Bit Mode Symbol Description Reset
15:0 WWKUP_IRQ_RST writing any value to this register will reset the interrupt. read-
ing always returns 0.
0x0
Table 49: WKUP_COUNTER_REG (0x50000106)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 REVENT_VALUE This value represents the number of events that have been
counted so far. It will be reset by resetting the interrupt.
0x0
Table 50: WKUP_RESET_CNTR_REG (0x50000108)
Bit Mode Symbol Description Reset
15:0 WWKUP_CNTR_RST writing any value to this register will reset the event counter 0x0
Table 51: WKUP_SELECT_P0_REG (0x5000010A)
Bit Mode Symbol Description Reset
7:0 R/W WKUP_SELECT_P0 0: input P0x is not enabled for wakeup event counter
1: input P0x is enabled for wakeup event counter
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 38 Final - January 29, 2015 v3.1
Table 52: WKUP_SELECT_P1_REG (0x5000010C)
Bit Mode Symbol Description Reset
5:0 R/W WKUP_SELECT_P1 0: input P1x is not enabled for wakeup event counter
1: input P1x is enabled for wakeup event counter
0x0
Table 53: WKUP_SELECT_P2_REG (0x5000010E)
Bit Mode Symbol Description Reset
9:0 R/W WKUP_SELECT_P2 0: input P2x is not enabled for wakeup event counter
1: input P2x is enabled for wakeup event counter
0x0
Table 54: WKUP_SELECT_P3_REG (0x50000110)
Bit Mode Symbol Description Reset
7:0 R/W WKUP_SELECT_P3 0: input P3x is not enabled for wakeup event counter
1: input P3x is enabled for wakeup event counter
0x0
Table 55: WKUP_POL_P0_REG (0x50000112)
Bit Mode Symbol Description Reset
7:0 R/W WKUP_POL_P0 0: enabled input P0x will increment the event counter if that
input goes high
1: enabled input P0x will increment the event counter if that
input goes low
0x0
Table 56: WKUP_POL_P1_REG (0x50000114)
Bit Mode Symbol Description Reset
5:0 R/W WKUP_POL_P1 0: enabled input P1x will increment the event counter if that
input goes high
1: enabled input P1x will increment the event counter if that
input goes low
0x0
Table 57: WKUP_POL_P2_REG (0x50000116)
Bit Mode Symbol Description Reset
9:0 R/W WKUP_POL_P2 0: enabled input P2x will increment the event counter if that
input goes high
1: enabled input P2x will increment the event counter if that
input goes low
0x0
Table 58: WKUP_POL_P3_REG (0x50000118)
Bit Mode Symbol Description Reset
7:0 R/W WKUP_POL_P3 0: enabled input P3x will increment the event counter if that
input goes high
1: enabled input P3x will increment the event counter if that
input goes low
0x0
Table 59: QDEC_CTRL_REG (0x50000200)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 39 Final - January 29, 2015 v3.1
9:3 R/W QD_IRQ_THRES The number of events on either counter (X or Y) that need to
be reached before an interrupt is generated. If 0 is written,
then threshold is considered to be 1.
0x2
2RQD_IRQ_STATUS Interrupt Status. If 1 an interrupt has occured. 0x0
1R/W QD_IRQ_CLR Writing 1 to this bit clears the interrupt. This bit is autocleared 0x0
0R/W QD_IRQ_MASK 0: interrupt is masked
1: interrupt is enabled
0x0
Table 59: QDEC_CTRL_REG (0x50000200)
Bit Mode Symbol Description Reset
Table 60: QDEC_XCNT_REG (0x50000202)
Bit Mode Symbol Description Reset
15:0 RX_COUNTER Contains a signed value of the events. Zero when channel is
disabled
0x0
Table 61: QDEC_YCNT_REG (0x50000204)
Bit Mode Symbol Description Reset
15:0 RY_COUNTER Contains a signed value of the events. Zero when channel is
disabled
0x0
Table 62: QDEC_CLOCKDIV_REG (0x50000206)
Bit Mode Symbol Description Reset
9:0 R/W CLOCK_DIVIDER Contains the number of the input clock cycles minus one, that
are required to generate one logic clock cycle.
0x0
Table 63: QDEC_CTRL2_REG (0x50000208)
Bit Mode Symbol Description Reset
15:12 --Reserved 0
11:8 R/W CHZ_PORT_SEL Defines which GPIOs are mapped on Channel Z
0: none
1: P0[0] -> CHZ_A, P0[1] -> CHZ_B
2: P0[2] -> CHZ_A, P0[3] -> CHZ_B
3: P0[4] -> CHZ_A, P0[5] -> CHZ_B
4: P0[6] -> CHZ_A, P0[7] -> CHZ_B
5: P1[0] -> CHZ_A, P1[1] -> CHZ_B
6: P1[2] -> CHZ_A, P1[3] -> CHZ_B
7: P2[3] -> CHZ_A, P2[4] -> CHZ_B
8: P2[5] -> CHZ_A, P2[6] -> CHZ_B
9: P2[7] -> CHZ_A, P2[8] -> CHZ_B
10: P2[9] -> CHZ_A, P2[0] -> CHZ_B
11..15: None
0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 40 Final - January 29, 2015 v3.1
7:4 R/W CHY_PORT_SEL Defines which GPIOs are mapped on Channel Y
0: none
1: P0[0] -> CHY_A, P0[1] -> CHY_B
2: P0[2] -> CHY_A, P0[3] -> CHY_B
3: P0[4] -> CHY_A, P0[5] -> CHY_B
4: P0[6] -> CHY_A, P0[7] -> CHY_B
5: P1[0] -> CHY_A, P1[1] -> CHY_B
6: P1[2] -> CHY_A, P1[3] -> CHY_B
7: P2[3] -> CHY_A, P2[4] -> CHY_B
8: P2[5] -> CHY_A, P2[6] -> CHY_B
9: P2[7] -> CHY_A, P2[8] -> CHY_B
10: P2[9] -> CHY_A, P2[0] -> CHY_B
11..15: None
0
3:0 R/W CHX_PORT_SEL Defines which GPIOs are mapped on Channel X
0: none
1: P0[0] -> CHX_A, P0[1] -> CHX_B
2: P0[2] -> CHX_A, P0[3] -> CHX_B
3: P0[4] -> CHX_A, P0[5] -> CHX_B
4: P0[6] -> CHX_A, P0[7] -> CHX_B
5: P1[0] -> CHX_A, P1[1] -> CHX_B
6: P1[2] -> CHX_A, P1[3] -> CHX_B
7: P2[3] -> CHX_A, P2[4] -> CHX_B
8: P2[5] -> CHX_A, P2[6] -> CHX_B
9: P2[7] -> CHX_A, P2[8] -> CHX_B
10: P2[9] -> CHX_A, P2[0] -> CHX_B
11..15: None
0
Table 63: QDEC_CTRL2_REG (0x50000208)
Bit Mode Symbol Description Reset
Table 64: QDEC_ZCNT_REG (0x5000020A)
Bit Mode Symbol Description Reset
15:0 RZ_COUNTER Contains a signed value of the events. Zero when channel is
disabled
0
Table 65: UART_RBR_THR_DLL_REG (0x50001000)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 41 Final - January 29, 2015 v3.1
7:0 R/W RBR_THR_DLL Receive Buffer Register: This register contains the data byte
received on the serial input port (sin) in UART mode or the
serial infrared input (sir_in) in infrared mode. The data in this
register is valid only if the Data Ready (DR) bit in the Line sta-
tus Register (LSR) is set. If FIFOs are disabled (FCR[0] set to
zero), the data in the RBR must be read before the next data
arrives, otherwise it will be overwritten, resulting in an overrun
error. If FIFOs are enabled (FCR[0] set to one), this register
accesses the head of the receive FIFO. If the receive FIFO is
full and this register is not read before the next data character
arrives, then the data already in the FIFO will be preserved
but any incoming data will be lost. An overrun error will also
occur. Transmit Holding Register: This register contains data
to be transmitted on the serial output port (sout) in UART
mode or the serial infrared output (sir_out_n) in infrared
mode. Data should only be written to the THR when the THR
Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost. Divisor Latch (Low): This
register makes up the lower 8-bits of a 16-bit, read/write, Divi-
sor Latch register that contains the baud rate divisor for the
UART. This register may only be accessed when the DLAB bit
(LCR[7]) is set. The output baud rate is equal to the serial
clock (sclk) frequency divided by sixteen times the value of
the baud rate divisor, as follows: baud rate = (serial clock freq)
/ (16 * divisor) Note that with the Divisor Latch Registers (DLL
and DLH) set to zero, the baud clock is disabled and no serial
communications will occur. Also, once the DLL is set, at least
8 clock cycles of the slowest DW_apb_uart clock should be
allowed to pass before transmitting or receiving data.
0x0
Table 65: UART_RBR_THR_DLL_REG (0x50001000)
Bit Mode Symbol Description Reset
Table 66: UART_IER_DLH_REG (0x50001004)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7R/W PTIME_DLH7 Interrupt Enable Register: PTIME, Programmable THRE
Interrupt Mode Enable. This is used to enable/disable the
generation of THRE Interrupt. 0 = disabled 1 = enabled Divi-
sor Latch (High): Bit[7] of the 8 bit DLH register.
0x0
6:4 --Reserved 0x0
3R/W EDSSI_DLH3 Interrupt Enable Register: EDSSI, Enable Modem Status
Interrupt. This is used to enable/disable the generation of
Modem Status Interrupt. This is the fourth highest priority
interrupt. 0 = disabled 1 = enabled Divisor Latch (High): Bit[3]
of the 8 bit DLH register
0x0
2R/W ELSI_DHL2 Interrupt Enable Register: ELSI, Enable Receiver Line Status
Interrupt. This is used to enable/disable the generation of
Receiver Line Status Interrupt. This is the highest priority
interrupt. 0 = disabled 1 = enabled Divisor Latch (High): Bit[2]
of the 8 bit DLH register.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 42 Final - January 29, 2015 v3.1
1R/W ETBEI_DLH1 Interrupt Enable Register: ETBEI, Enable Transmit Holding
Register Empty Interrupt. This is used to enable/disable the
generation of Transmitter Holding Register Empty Interrupt.
This is the third highest priority interrupt. 0 = disabled 1 = ena-
bled Divisor Latch (High): Bit[1] of the 8 bit DLH register.
0x0
0R/W ERBFI_DLH0 Interrupt Enable Register: ERBFI, Enable Received Data
Available Interrupt. This is used to enable/disable the genera-
tion of Received Data Available Interrupt and the Character
Timeout Interrupt (if in FIFO mode and FIFO's enabled).
These are the second highest priority interrupts. 0 = disabled
1 = enabled Divisor Latch (High): Bit[0] of the 8 bit DLH regis-
ter.
0x0
Table 66: UART_IER_DLH_REG (0x50001004)
Bit Mode Symbol Description Reset
Table 67: UART_IIR_FCR_REG (0x50001008)
Bit Mode Symbol Description Reset
15:0 R/W IIR_FCR Interrupt Identification Register, reading this register; FIFO
Control Register, writing to this register. Interrupt Identification
Register: Bits[7:6], FIFO's Enabled (or FIFOSE): This is used
to indicate whether the FIFO's are enabled or disabled. 00 =
disabled. 11 = enabled. Bits[3:0], Interrupt ID (or IID): This
indicates the highest priority pending interrupt which can be
one of the following types: 0000 = modem status. 0001 = no
interrupt pending. 0010 = THR empty. 0100 = received data
available. 0110 = receiver line status. 0111 = busy detect.
1100 = character timeout. Bits[7:6], RCVR Trigger (or RT):.
This is used to select the trigger level in the receiver FIFO at
which the Received Data Available Interrupt will be gener-
ated. In auto flow control mode it is used to determine when
the rts_n signal will be de-asserted. It also determines when
the dma_rx_req_n signal will be asserted when in certain
modes of operation. The following trigger levels are sup-
ported: 00 = 1 character in the FIFO 01 = FIFO 1/4 full 10 =
FIFO 1/2 full 11 = FIFO 2 less than full Bits[5:4], TX Empty
Trigger (or TET): This is used to select the empty threshold
level at which the THRE Interrupts will be generated when the
mode is active. It also determines when the dma_tx_req_n
signal will be asserted when in certain modes of operation.
The following trigger levels are supported: 00 = FIFO empty
01 = 2 characters in the FIFO 10 = FIFO 1/4 full 11 = FIFO 1/
2 full Bit[3], DMA Mode (or DMAM): This determines the DMA
signalling mode used for the dma_tx_req_n and
dma_rx_req_n output signals. 0 = mode 0 1 = mode 1 Bit[2],
XMIT FIFO Reset (or XFIFOR): This resets the control portion
of the transmit FIFO and treats the FIFO as empty. Note that
this bit is 'self-clearing' and it is not necessary to clear this bit.
Bit[1], RCVR FIFO Reset (or RFIFOR): This resets the control
portion of the receive FIFO and treats the FIFO as empty.
Note that this bit is 'self-clearing' and it is not necessary to
clear this bit. Bit[0], FIFO Enable (or FIFOE): This enables/
disables the transmit (XMIT) and receive (RCVR) FIFO's.
Whenever the value of this bit is changed both the XMIT and
RCVR controller portion of FIFO's will be reset.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 43 Final - January 29, 2015 v3.1
Table 68: UART_LCR_REG (0x5000100C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7R/W UART_DLAB Divisor Latch Access Bit.
This bit is used to enable reading and writing of the Divisor
Latch register (DLL and DLH) to set the baud rate of the
UART.
This bit must be cleared after initial baud rate setup in order to
access other registers.
0x0
6R/W UART_BC Break Control Bit.
This is used to cause a break condition to be transmitted to
the receiving device. If set to one the serial output is forced to
the spacing (logic 0) state. When not in Loopback Mode, as
determined by MCR[4], the sout line is forced low until the
Break bit is cleared. If active (MCR[6] set to one) the
sir_out_n line is continuously pulsed. When in Loopback
Mode, the break condition is internally looped back to the
receiver and the sir_out_n line is forced low.
0x0
5--Reserved 0x0
4R/W UART_EPS Even Parity Select.
This is used to select between even and odd parity, when par-
ity is enabled (PEN set to one). If set to one, an even number
of logic 1s is transmitted or checked. If set to zero, an odd
number of logic 1s is transmitted or checked.
0x0
3R/W UART_PEN Parity Enable.
This bit is used to enable and disable parity generation and
detection in transmitted and received serial character respec-
tively.
0 = parity disabled
1 = parity enabled
0x0
2R/W UART_STOP Number of stop bits.
This is used to select the number of stop bits per character
that the peripheral transmits and receives. If set to zero, one
stop bit is transmitted in the serial data.
If set to one and the data bits are set to 5 (LCR[1:0] set to
zero) one and a half stop bits is transmitted. Otherwise, two
stop bits are transmitted. Note that regardless of the number
of stop bits selected, the receiver checks only the first stop bit.
0 = 1 stop bit
1 = 1.5 stop bits when DLS (LCR[1:0]) is zero, else 2 stop bit
0x0
1:0 R/W UART_DLS Data Length Select.
This is used to select the number of data bits per character
that the peripheral transmits and receives. The number of bit
that may be selected areas follows:
00 = 5 bits
01 = 6 bits
10 = 7 bits
11 = 8 bits
0x0
Table 69: UART_MCR_REG (0x50001010)
Bit Mode Symbol Description Reset
15:7 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 44 Final - January 29, 2015 v3.1
6R/W UART_SIRE SIR Mode Enable.
This is used to enable/disable the IrDA SIR Mode features as
described in "IrDA 1.0 SIR Protocol" on page 53.
0 = IrDA SIR Mode disabled
1 = IrDA SIR Mode enabled
0x0
5R/W UART_AFCE Auto Flow Control Enable.
When FIFOs are enabled and the Auto Flow Control Enable
(AFCE) bit is set, hardware Auto Flow Control is enabled via
CTS and RTS.
0 = Auto Flow Control Mode disabled
1 = Auto Flow Control Mode enabled
0x0
4R/W UART_LB LoopBack Bit.
This is used to put the UART into a diagnostic mode for test
purposes.
If operating in UART mode (SIR_MODE not active, MCR[6]
set to zero), data on the sout line is held high, while serial
data output is looped back to the sin line, internally. In this
mode all the interrupts are fully functional. Also, in loopback
mode, the modem control inputs (dsr_n, cts_n, ri_n, dcd_n)
are disconnected and the modem control outputs (dtr_n,
rts_n, out1_n, out2_n) are looped back to the inputs, inter-
nally.
If operating in infrared mode (SIR_MODE active, MCR[6] set
to one), data on the sir_out_n line is held low, while serial data
output is inverted and looped back to the sir_in line.
0x0
3R/W UART_OUT2 OUT2.
This is used to directly control the user-designated Output2
(out2_n) output. The value written to this location is inverted
and driven out on out2_n, that is:
0 = out2_n de-asserted (logic 1)
1 = out2_n asserted (logic 0)
Note that in Loopback mode (MCR[4] set to one), the out2_n
output is held inactive high while the value of this location is
internally looped back to an input.
0x0
2R/W UART_OUT1 OUT1.
This is used to directly control the user-designated Output1
(out1_n) output. The value written to this location is inverted
and driven out on out1_n, that is:
0 = out1_n de-asserted (logic 1)
1 = out1_n asserted (logic 0)
Note that in Loopback mode (MCR[4] set to one), the out1_n
output is held inactive high while the value of this location is
internally looped back to an input.
0x0
Table 69: UART_MCR_REG (0x50001010)
Bit Mode Symbol Description Reset
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 45 Final - January 29, 2015 v3.1
1R/W UART_RTS Request to Send.
This is used to directly control the Request to Send (rts_n)
output. The Request To Send (rts_n) output is used to inform
the modem or data set that the UART is ready to exchange
data.
When Auto Flow Control is disabled (MCR[5] set to zero), the
rts_n signal is set low by programming MCR[1] (RTS) to a
high. When Auto Flow Control is enabled (MCR[5] set to one)
and FIFOs are enabled (FCR[0] set to one), the rts_n output
is controlled in the same way, but is also gated with the
receiver FIFO threshold trigger (rts_n is inactive high when
above the threshold). The rts_n signal is de-asserted when
MCR[1] is set low.
Note that in Loopback mode (MCR[4] set to one), the rts_n
output is held inactive (high) while the value of this location is
internally looped back to an input.
0x0
0--Reserved 0x0
Table 69: UART_MCR_REG (0x50001010)
Bit Mode Symbol Description Reset
Table 70: UART_LSR_REG (0x50001014)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7RUART_RFE Receiver FIFO Error bit.
This bit is only relevant when FIFOs are enabled (FCR[0] set
to one). This is used to indicate if there is at least one parity
error, framing error, or break indication in the FIFO.
0 = no error in RX FIFO
1 = error in RX FIFO
This bit is cleared when the LSR is read and the character
with the error is at the top of the receiver FIFO and there are
no subsequent errors in the FIFO.
0x0
6RUART_TEMT Transmitter Empty bit.
If FIFOs enabled (FCR[0] set to one), this bit is set whenever
the Transmitter Shift Register and the FIFO are both empty. If
FIFOs are disabled, this bit is set whenever the Transmitter
Holding Register and the Transmitter Shift Register are both
empty.
0x1
5RUART_THRE Transmit Holding Register Empty bit.
If THRE mode is disabled (IER[7] set to zero) and regardless
of FIFO's being implemented/enabled or not, this bit indicates
that the THR or TX FIFO is empty.
This bit is set whenever data is transferred from the THR or
TX FIFO to the transmitter shift register and no new data has
been written to the THR or TX FIFO. This also causes a
THRE Interrupt to occur, if the THRE Interrupt is enabled. If
both modes are active (IER[7] set to one and FCR[0] set to
one respectively), the functionality is switched to indicate the
transmitter FIFO is full, and no longer controls THRE inter-
rupts, which are then controlled by the FCR[5:4] threshold
setting.
0x1
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 46 Final - January 29, 2015 v3.1
4RUART_B1 Break Interrupt bit.
This is used to indicate the detection of a break sequence on
the serial input data.
If in UART mode (SIR_MODE == Disabled), it is set whenever
the serial input, sin, is held in a logic '0' state for longer than
the sum of start time + data bits + parity + stop bits.
If in infrared mode (SIR_MODE == Enabled), it is set when-
ever the serial input, sir_in, is continuously pulsed to logic '0'
for longer than the sum of start time + data bits + parity + stop
bits. A break condition on serial input causes one and only
one character, consisting of all zeros, to be received by the
UART.
In the FIFO mode, the character associated with the break
condition is carried through the FIFO and is revealed when
the character is at the top of the FIFO.
Reading the LSR clears the BI bit. In the non-FIFO mode, the
BI indication occurs immediately and persists until the LSR is
read.
0x0
3RUART_FE Framing Error bit.
This is used to indicate the occurrence of a framing error in
the receiver. A framing error occurs when the receiver does
not detect a valid STOP bit in the received data.
In the FIFO mode, since the framing error is associated with a
character received, it is revealed when the character with the
framing error is at the top of the FIFO.
When a framing error occurs, the UART tries to resynchro-
nize. It does this by assuming that the error was due to the
start bit of the next character and then continues receiving the
other bit i.e. data, and/or parity and stop. It should be noted
that the Framing Error (FE) bit (LSR[3]) is set if a break inter-
rupt has occurred, as indicated by Break Interrupt (BI) bit
(LSR[4]).
0 = no framing error
1 = framing error
Reading the LSR clears the FE bit.
0x0
2RUART_PE Parity Error bit.
This is used to indicate the occurrence of a parity error in the
receiver if the Parity Enable (PEN) bit (LCR[3]) is set.
In the FIFO mode, since the parity error is associated with a
character received, it is revealed when the character with the
parity error arrives at the top of the FIFO.
It should be noted that the Parity Error (PE) bit (LSR[2]) is set
if a break interrupt has occurred, as indicated by Break Inter-
rupt (BI) bit (LSR[4]).
0 = no parity error
1 = parity error
Reading the LSR clears the PE bit.
0x0
Table 70: UART_LSR_REG (0x50001014)
Bit Mode Symbol Description Reset
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 47 Final - January 29, 2015 v3.1
1RUART_OE Overrun error bit.
This is used to indicate the occurrence of an overrun error.
This occurs if a new data character was received before the
previous data was read.
In the non-FIFO mode, the OE bit is set when a new character
arrives in the receiver before the previous character was read
from the RBR. When this happens, the data in the RBR is
overwritten. In the FIFO mode, an overrun error occurs when
the FIFO is full and a new character arrives at the receiver.
The data in the FIFO is retained and the data in the receive
shift register is lost.
0 = no overrun error
1 = overrun error
Reading the LSR clears the OE bit.
0x0
0RUART_DR Data Ready bit.
This is used to indicate that the receiver contains at least one
character in the RBR or the receiver FIFO.
0 = no data ready
1 = data ready
This bit is cleared when the RBR is read in non-FIFO mode,
or when the receiver FIFO is empty, in FIFO mode.
0x0
Table 70: UART_LSR_REG (0x50001014)
Bit Mode Symbol Description Reset
Table 71: UART_MSR_REG (0x50001018)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7RUART_DCD Data Carrier Detect.
This is used to indicate the current state of the modem control
line dcd_n. This bit is the complement of dcd_n. When the
Data Carrier Detect input (dcd_n) is asserted it is an indica-
tion that the carrier has been detected by the modem or data
set.
0 = dcd_n input is de-asserted (logic 1)
1 = dcd_n input is asserted (logic 0)
In Loopback Mode (MCR[4] set to one), DCD is the same as
MCR[3] (Out2).
0x0
6RUART_R1 Ring Indicator.
This is used to indicate the current state of the modem control
line ri_n. This bit is the complement of ri_n. When the Ring
Indicator input (ri_n) is asserted it is an indication that a tele-
phone ringing signal has been received by the modem or data
set.
0 = ri_n input is de-asserted (logic 1)
1 = ri_n input is asserted (logic 0)
In Loopback Mode (MCR[4] set to one), RI is the same as
MCR[2] (Out1).
0x0
5--Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 48 Final - January 29, 2015 v3.1
4RUART_CTS Clear to Send.
This is used to indicate the current state of the modem control
line cts_n. This bit is the complement of cts_n. When the
Clear to Send input (cts_n) is asserted it is an indication that
the modem or data set is ready to exchange data with the
UART Ctrl.
0 = cts_n input is de-asserted (logic 1)
1 = cts_n input is asserted (logic 0)
In Loopback Mode (MCR[4] = 1), CTS is the same as MCR[1]
(RTS).
0x0
3RUART_DDCD Delta Data Carrier Detect.
This is used to indicate that the modem control line dcd_n has
changed since the last time the MSR was read.
0 = no change on dcd_n since last read of MSR
1 = change on dcd_n since last read of MSR
Reading the MSR clears the DDCD bit. In Loopback Mode
(MCR[4] = 1), DDCD reflects changes on MCR[3] (Out2).
Note, if the DDCD bit is not set and the dcd_n signal is
asserted (low) and a reset occurs (software or otherwise),
then the DDCD bit is set when the reset is removed if the
dcd_n signal remains asserted.
0x0
2RUART_TERI Trailing Edge of Ring Indicator.
This is used to indicate that a change on the input ri_n (from
an active-low to an inactive-high state) has occurred since the
last time the MSR was read.
0 = no change on ri_n since last read of MSR
1 = change on ri_n since last read of MSR
Reading the MSR clears the TERI bit. In Loopback Mode
(MCR[4] = 1), TERI reflects when MCR[2] (Out1) has
changed state from a high to a low.
0x0
1--Reserved 0x0
0RUART_DCTS Delta Clear to Send.
This is used to indicate that the modem control line cts_n has
changed since the last time the MSR was read.
0 = no change on cts_n since last read of MSR
1 = change on cts_n since last read of MSR
Reading the MSR clears the DCTS bit. In Loopback Mode
(MCR[4] = 1), DCTS reflects changes on MCR[1] (RTS).
Note, if the DCTS bit is not set and the cts_n signal is
asserted (low) and a reset occurs (software or otherwise),
then the DCTS bit is set when the reset is removed if the
cts_n signal remains asserted.
0x0
Table 71: UART_MSR_REG (0x50001018)
Bit Mode Symbol Description Reset
Table 72: UART_SCR_REG (0x5000101C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W UART_SCRATCH_PA
D
This register is for programmers to use as a temporary stor-
age space. It has no defined purpose in the UART Ctrl.
0x0
Table 73: UART_LPDLL_REG (0x50001020)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 49 Final - January 29, 2015 v3.1
7:0 R/W UART_LPDLL This register makes up the lower 8-bits of a 16-bit, read/write,
Low Power Divisor Latch register that contains the baud rate
divisor for the UART, which must give a baud rate of 115.2K.
This is required for SIR Low Power (minimum pulse width)
detection at the receiver. This register may be accessed only
when the DLAB bit (LCR[7]) is set.
The output low-power baud rate is equal to the serial clock
(sclk) frequency divided by sixteen times the value of the
baud rate divisor, as follows:
Low power baud rate = (serial clock frequency)/(16* divisor)
Therefore, a divisor must be selected to give a baud rate of
115.2K.
NOTE: When the Low Power Divisor Latch registers (LPDLL
and LPDLH) are set to 0, the low-power baud clock is disa-
bled and no low-power pulse detection (or any pulse detec-
tion) occurs at the receiver. Also, once the LPDLL is set, at
least eight clock cycles of the slowest UART Ctrl clock should
be allowed to pass before transmitting or receiving data.
0x0
Table 73: UART_LPDLL_REG (0x50001020)
Bit Mode Symbol Description Reset
Table 74: UART_LPDLH_REG (0x50001024)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W UART_LPDLH This register makes up the upper 8-bits of a 16-bit, read/write,
Low Power Divisor Latch register that contains the baud rate
divisor for the UART, which must give a baud rate of 115.2K.
This is required for SIR Low Power (minimum pulse width)
detection at the receiver. This register may be accessed only
when the DLAB bit (LCR[7]) is set.
The output low-power baud rate is equal to the serial clock
(sclk) frequency divided by sixteen times the value of the
baud rate divisor, as follows:
Low power baud rate = (serial clock frequency)/(16* divisor)
Therefore, a divisor must be selected to give a baud rate of
115.2K.
NOTE: When the Low Power Divisor Latch registers (LPDLL
and LPDLH) are set to 0, the low-power baud clock is disa-
bled and no low-power pulse detection (or any pulse detec-
tion) occurs at the receiver. Also, once the LPDLH is set, at
least eight clock cycles of the slowest UART Ctrl clock should
be allowed to pass before transmitting or receiving data.
0x0
Table 75: UART_SRBR_STHR0_REG (0x50001030)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 50 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 75: UART_SRBR_STHR0_REG (0x50001030)
Bit Mode Symbol Description Reset
Table 76: UART_SRBR_STHR1_REG (0x50001034)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 51 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 76: UART_SRBR_STHR1_REG (0x50001034)
Bit Mode Symbol Description Reset
Table 77: UART_SRBR_STHR2_REG (0x50001038)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 52 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 77: UART_SRBR_STHR2_REG (0x50001038)
Bit Mode Symbol Description Reset
Table 78: UART_SRBR_STHR3_REG (0x5000103C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 53 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 78: UART_SRBR_STHR3_REG (0x5000103C)
Bit Mode Symbol Description Reset
Table 79: UART_SRBR_STHR4_REG (0x50001040)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 54 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 79: UART_SRBR_STHR4_REG (0x50001040)
Bit Mode Symbol Description Reset
Table 80: UART_SRBR_STHR5_REG (0x50001044)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 55 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 80: UART_SRBR_STHR5_REG (0x50001044)
Bit Mode Symbol Description Reset
Table 81: UART_SRBR_STHR6_REG (0x50001048)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 56 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 81: UART_SRBR_STHR6_REG (0x50001048)
Bit Mode Symbol Description Reset
Table 82: UART_SRBR_STHR7_REG (0x5000104C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 57 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 82: UART_SRBR_STHR7_REG (0x5000104C)
Bit Mode Symbol Description Reset
Table 83: UART_SRBR_STHR8_REG (0x50001050)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 58 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 83: UART_SRBR_STHR8_REG (0x50001050)
Bit Mode Symbol Description Reset
Table 84: UART_SRBR_STHR9_REG (0x50001054)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 59 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 84: UART_SRBR_STHR9_REG (0x50001054)
Bit Mode Symbol Description Reset
Table 85: UART_SRBR_STHR10_REG (0x50001058)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 60 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 85: UART_SRBR_STHR10_REG (0x50001058)
Bit Mode Symbol Description Reset
Table 86: UART_SRBR_STHR11_REG (0x5000105C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 61 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 86: UART_SRBR_STHR11_REG (0x5000105C)
Bit Mode Symbol Description Reset
Table 87: UART_SRBR_STHR12_REG (0x50001060)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 62 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 87: UART_SRBR_STHR12_REG (0x50001060)
Bit Mode Symbol Description Reset
Table 88: UART_SRBR_STHR13_REG (0x50001064)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 63 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 88: UART_SRBR_STHR13_REG (0x50001064)
Bit Mode Symbol Description Reset
Table 89: UART_SRBR_STHR14_REG (0x50001068)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 64 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 89: UART_SRBR_STHR14_REG (0x50001068)
Bit Mode Symbol Description Reset
Table 90: UART_SRBR_STHR15_REG (0x5000106C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 65 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 90: UART_SRBR_STHR15_REG (0x5000106C)
Bit Mode Symbol Description Reset
Table 91: UART_USR_REG (0x5000107C)
Bit Mode Symbol Description Reset
15:5 --Reserved 0x0
4RUART_RFF Receive FIFO Full.
This is used to indicate that the receive FIFO is completely
full.
0 = Receive FIFO not full
1 = Receive FIFO Full
This bit is cleared when the RX FIFO is no longer full.
0x0
3RUART_RFNE Receive FIFO Not Empty.
This is used to indicate that the receive FIFO contains one or
more entries.
0 = Receive FIFO is empty
1 = Receive FIFO is not empty
This bit is cleared when the RX FIFO is empty.
0x0
2RUART_TFE Transmit FIFO Empty.
This is used to indicate that the transmit FIFO is completely
empty.
0 = Transmit FIFO is not empty
1 = Transmit FIFO is empty
This bit is cleared when the TX FIFO is no longer empty.
0x1
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 66 Final - January 29, 2015 v3.1
1RUART_TFNF Transmit FIFO Not Full.
This is used to indicate that the transmit FIFO in not full.
0 = Transmit FIFO is full
1 = Transmit FIFO is not full
This bit is cleared when the TX FIFO is full.
0x1
0--Reserved 0x0
Table 91: UART_USR_REG (0x5000107C)
Bit Mode Symbol Description Reset
Table 92: UART_TFL_REG (0x50001080)
Bit Mode Symbol Description Reset
15:0 RUART_TRANSMIT_FI
FO_LEVEL
Transmit FIFO Level.
This is indicates the number of data entries in the transmit
FIFO.
0x0
Table 93: UART_RFL_REG (0x50001084)
Bit Mode Symbol Description Reset
15:0 RUART_RECEIVE_FIF
O_LEVEL
Receive FIFO Level.
This is indicates the number of data entries in the receive
FIFO.
0x0
Table 94: UART_SRR_REG (0x50001088)
Bit Mode Symbol Description Reset
15:3 --Reserved 0x0
2WUART_XFR XMIT FIFO Reset.
This is a shadow register for the XMIT FIFO Reset bit
(FCR[2]). This can be used to remove the burden on software
having to store previously written FCR values (which are
pretty static) just to reset the transmit FIFO. This resets the
control portion of the transmit FIFO and treats the FIFO as
empty. Note that this bit is 'self-clearing'. It is not necessary to
clear this bit.
0x0
1WUART_RFR RCVR FIFO Reset.
This is a shadow register for the RCVR FIFO Reset bit
(FCR[1]). This can be used to remove the burden on software
having to store previously written FCR values (which are
pretty static) just to reset the receive FIFO This resets the
control portion of the receive FIFO and treats the FIFO as
empty.
Note that this bit is 'self-clearing'. It is not necessary to clear
this bit.
0x0
0WUART_UR UART Reset. This asynchronously resets the UART Ctrl and
synchronously removes the reset assertion. For a two clock
implementation both pclk and sclk domains are reset.
0x0
Table 95: UART_SRTS_REG (0x5000108C)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 67 Final - January 29, 2015 v3.1
0R/W UART_SHADOW_RE
QUEST_TO_SEND
Shadow Request to Send.
This is a shadow register for the RTS bit (MCR[1]), this can be
used to remove the burden of having to perform a read-mod-
ify-write on the MCR. This is used to directly control the
Request to Send (rts_n) output. The Request To Send (rts_n)
output is used to inform the modem or data set that the UART
Ctrl is ready to exchange data.
When Auto Flow Control is disabled (MCR[5] = 0), the rts_n
signal is set low by programming MCR[1] (RTS) to a high.
When Auto Flow Control is enabled (MCR[5] = 1) and FIFOs
are enabled (FCR[0] = 1), the rts_n output is controlled in the
same way, but is also gated with the receiver FIFO threshold
trigger (rts_n is inactive high when above the threshold).
Note that in Loopback mode (MCR[4] = 1), the rts_n output is
held inactive-high while the value of this location is internally
looped back to an input.
0x0
Table 95: UART_SRTS_REG (0x5000108C)
Bit Mode Symbol Description Reset
Table 96: UART_SBCR_REG (0x50001090)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0R/W UART_SHADOW_BR
EAK_CONTROL
Shadow Break Control Bit.
This is a shadow register for the Break bit (LCR[6]), this can
be used to remove the burden of having to performing a read
modify write on the LCR. This is used to cause a break condi-
tion to be transmitted to the receiving device.
If set to one the serial output is forced to the spacing (logic 0)
state. When not in Loopback Mode, as determined by
MCR[4], the sout line is forced low until the Break bit is
cleared.
If SIR_MODE active (MCR[6] = 1) the sir_out_n line is contin-
uously pulsed. When in Loopback Mode, the break condition
is internally looped back to the receiver.
0x0
Table 97: UART_SDMAM_REG (0x50001094)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0R/W UART_SHADOW_DM
A_MODE
Shadow DMA Mode.
This is a shadow register for the DMA mode bit (FCR[3]). This
can be used to remove the burden of having to store the pre-
viously written value to the FCR in memory and having to
mask this value so that only the DMA Mode bit gets updated.
This determines the DMA signalling mode used for the
dma_tx_req_n and dma_rx_req_n output signals.
0 = mode 0
1 = mode 1
0x0
Table 98: UART_SFE_REG (0x50001098)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 68 Final - January 29, 2015 v3.1
0R/W UART_SHADOW_FIF
O_ENABLE
Shadow FIFO Enable.
This is a shadow register for the FIFO enable bit (FCR[0]).
This can be used to remove the burden of having to store the
previously written value to the FCR in memory and having to
mask this value so that only the FIFO enable bit gets
updated.This enables/disables the transmit (XMIT) and
receive (RCVR) FIFOs. If this bit is set to zero (disabled) after
being enabled then both the XMIT and RCVR controller por-
tion of FIFOs are reset.
0x0
Table 98: UART_SFE_REG (0x50001098)
Bit Mode Symbol Description Reset
Table 99: UART_SRT_REG (0x5000109C)
Bit Mode Symbol Description Reset
15:2 --Reserved 0x0
1:0 R/W UART_SHADOW_RC
VR_TRIGGER
Shadow RCVR Trigger.
This is a shadow register for the RCVR trigger bits (FCR[7:6]).
This can be used to remove the burden of having to store the
previously written value to the FCR in memory and having to
mask this value so that only the RCVR trigger bit gets
updated.
This is used to select the trigger level in the receiver FIFO at
which the Received Data Available Interrupt is generated. It
also determines when the dma_rx_req_n signal is asserted
when DMA Mode (FCR[3]) = 1. The following trigger levels
are supported:
00 = 1 character in the FIFO
01 = FIFO ¼ full
10 = FIFO ½ full
11 = FIFO 2 less than full
0x0
Table 100: UART_STET_REG (0x500010A0)
Bit Mode Symbol Description Reset
15:2 --Reserved 0x0
1:0 R/W UART_SHADOW_TX
_EMPTY_TRIGGER
Shadow TX Empty Trigger.
This is a shadow register for the TX empty trigger bits
(FCR[5:4]). This can be used to remove the burden of having
to store the previously written value to the FCR in memory
and having to mask this value so that only the TX empty trig-
ger bit gets updated.
This is used to select the empty threshold level at which the
THRE Interrupts are generated when the mode is active. The
following trigger levels are supported:
00 = FIFO empty
01 = 2 characters in the FIFO
10 = FIFO ¼ full
11 = FIFO ½ full
0x0
Table 101: UART_HTX_REG (0x500010A4)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 69 Final - January 29, 2015 v3.1
0R/W UART_HALT_TX This register is use to halt transmissions for testing, so that
the transmit FIFO can be filled by the master when FIFOs are
implemented and enabled.
0 = Halt TX disabled
1 = Halt TX enabled
Note, if FIFOs are implemented and not enabled, the setting
of the halt TX register has no effect on operation.
0x0
Table 101: UART_HTX_REG (0x500010A4)
Bit Mode Symbol Description Reset
Table 102: UART_CPR_REG (0x500010F4)
Bit Mode Symbol Description Reset
15:0 RCPR Component Parameter Register 0x0
Table 103: UART_UCV_REG (0x500010F8)
Bit Mode Symbol Description Reset
15:0 RUCV Component Version 0x333038
2A
Table 104: UART_CTR_REG (0x500010FC)
Bit Mode Symbol Description Reset
15:0 RCTR Component Type Register 0x445701
10
Table 105: UART2_RBR_THR_DLL_REG (0x50001100)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 70 Final - January 29, 2015 v3.1
7:0 R/W RBR_THR_DLL Receive Buffer Register: This register contains the data byte
received on the serial input port (sin) in UART mode or the
serial infrared input (sir_in) in infrared mode. The data in this
register is valid only if the Data Ready (DR) bit in the Line sta-
tus Register (LSR) is set. If FIFOs are disabled (FCR[0] set to
zero), the data in the RBR must be read before the next data
arrives, otherwise it will be overwritten, resulting in an overrun
error. If FIFOs are enabled (FCR[0] set to one), this register
accesses the head of the receive FIFO. If the receive FIFO is
full and this register is not read before the next data character
arrives, then the data already in the FIFO will be preserved
but any incoming data will be lost. An overrun error will also
occur. Transmit Holding Register: This register contains data
to be transmitted on the serial output port (sout) in UART
mode or the serial infrared output (sir_out_n) in infrared
mode. Data should only be written to the THR when the THR
Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost. Divisor Latch (Low): This
register makes up the lower 8-bits of a 16-bit, read/write, Divi-
sor Latch register that contains the baud rate divisor for the
UART. This register may only be accessed when the DLAB bit
(LCR[7]) is set. The output baud rate is equal to the serial
clock (sclk) frequency divided by sixteen times the value of
the baud rate divisor, as follows: baud rate = (serial clock freq)
/ (16 * divisor) Note that with the Divisor Latch Registers (DLL
and DLH) set to zero, the baud clock is disabled and no serial
communications will occur. Also, once the DLL is set, at least
8 clock cycles of the slowest DW_apb_uart clock should be
allowed to pass before transmitting or receiving data.
0x0
Table 105: UART2_RBR_THR_DLL_REG (0x50001100)
Bit Mode Symbol Description Reset
Table 106: UART2_IER_DLH_REG (0x50001104)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7R/W PTIME_DLH7 Interrupt Enable Register: PTIME, Programmable THRE
Interrupt Mode Enable. This is used to enable/disable the
generation of THRE Interrupt. 0 = disabled 1 = enabled Divi-
sor Latch (High): Bit[7] of the 8 bit DLH register.
0x0
6:4 --Reserved 0x0
3R/W EDSSI_DLH3 Interrupt Enable Register: EDSSI, Enable Modem Status
Interrupt. This is used to enable/disable the generation of
Modem Status Interrupt. This is the fourth highest priority
interrupt. 0 = disabled 1 = enabled Divisor Latch (High): Bit[3]
of the 8 bit DLH register
0x0
2R/W ELSI_DHL2 Interrupt Enable Register: ELSI, Enable Receiver Line Status
Interrupt. This is used to enable/disable the generation of
Receiver Line Status Interrupt. This is the highest priority
interrupt. 0 = disabled 1 = enabled Divisor Latch (High): Bit[2]
of the 8 bit DLH register.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 71 Final - January 29, 2015 v3.1
1R/W ETBEI_DLH1 Interrupt Enable Register: ETBEI, Enable Transmit Holding
Register Empty Interrupt. This is used to enable/disable the
generation of Transmitter Holding Register Empty Interrupt.
This is the third highest priority interrupt. 0 = disabled 1 = ena-
bled Divisor Latch (High): Bit[1] of the 8 bit DLH register.
0x0
0R/W ERBFI_DLH0 Interrupt Enable Register: ERBFI, Enable Received Data
Available Interrupt. This is used to enable/disable the genera-
tion of Received Data Available Interrupt and the Character
Timeout Interrupt (if in FIFO mode and FIFO's enabled).
These are the second highest priority interrupts. 0 = disabled
1 = enabled Divisor Latch (High): Bit[0] of the 8 bit DLH regis-
ter.
0x0
Table 106: UART2_IER_DLH_REG (0x50001104)
Bit Mode Symbol Description Reset
Table 107: UART2_IIR_FCR_REG (0x50001108)
Bit Mode Symbol Description Reset
15:0 R/W IIR_FCR Interrupt Identification Register, reading this register; FIFO
Control Register, writing to this register. Interrupt Identification
Register: Bits[7:6], FIFO's Enabled (or FIFOSE): This is used
to indicate whether the FIFO's are enabled or disabled. 00 =
disabled. 11 = enabled. Bits[3:0], Interrupt ID (or IID): This
indicates the highest priority pending interrupt which can be
one of the following types: 0000 = modem status. 0001 = no
interrupt pending. 0010 = THR empty. 0100 = received data
available. 0110 = receiver line status. 0111 = busy detect.
1100 = character timeout. Bits[7:6], RCVR Trigger (or RT):.
This is used to select the trigger level in the receiver FIFO at
which the Received Data Available Interrupt will be gener-
ated. In auto flow control mode it is used to determine when
the rts_n signal will be de-asserted. It also determines when
the dma_rx_req_n signal will be asserted when in certain
modes of operation. The following trigger levels are sup-
ported: 00 = 1 character in the FIFO 01 = FIFO 1/4 full 10 =
FIFO 1/2 full 11 = FIFO 2 less than full Bits[5:4], TX Empty
Trigger (or TET): This is used to select the empty threshold
level at which the THRE Interrupts will be generated when the
mode is active. It also determines when the dma_tx_req_n
signal will be asserted when in certain modes of operation.
The following trigger levels are supported: 00 = FIFO empty
01 = 2 characters in the FIFO 10 = FIFO 1/4 full 11 = FIFO 1/
2 full Bit[3], DMA Mode (or DMAM): This determines the DMA
signalling mode used for the dma_tx_req_n and
dma_rx_req_n output signals. 0 = mode 0 1 = mode 1 Bit[2],
XMIT FIFO Reset (or XFIFOR): This resets the control portion
of the transmit FIFO and treats the FIFO as empty. Note that
this bit is 'self-clearing' and it is not necessary to clear this bit.
Bit[1], RCVR FIFO Reset (or RFIFOR): This resets the control
portion of the receive FIFO and treats the FIFO as empty.
Note that this bit is 'self-clearing' and it is not necessary to
clear this bit. Bit[0], FIFO Enable (or FIFOE): This enables/
disables the transmit (XMIT) and receive (RCVR) FIFO's.
Whenever the value of this bit is changed both the XMIT and
RCVR controller portion of FIFO's will be reset.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 72 Final - January 29, 2015 v3.1
Table 108: UART2_LCR_REG (0x5000110C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7R/W UART_DLAB Divisor Latch Access Bit.
This bit is used to enable reading and writing of the Divisor
Latch register (DLL and DLH) to set the baud rate of the
UART.
This bit must be cleared after initial baud rate setup in order to
access other registers.
0x0
6R/W UART_BC Break Control Bit.
This is used to cause a break condition to be transmitted to
the receiving device. If set to one the serial output is forced to
the spacing (logic 0) state. When not in Loopback Mode, as
determined by MCR[4], the sout line is forced low until the
Break bit is cleared. If active (MCR[6] set to one) the
sir_out_n line is continuously pulsed. When in Loopback
Mode, the break condition is internally looped back to the
receiver and the sir_out_n line is forced low.
0x0
5--Reserved 0x0
4R/W UART_EPS Even Parity Select.
This is used to select between even and odd parity, when par-
ity is enabled (PEN set to one). If set to one, an even number
of logic 1s is transmitted or checked. If set to zero, an odd
number of logic 1s is transmitted or checked.
0x0
3R/W UART_PEN Parity Enable.
This bit is used to enable and disable parity generation and
detection in transmitted and received serial character respec-
tively.
0 = parity disabled
1 = parity enabled
0x0
2R/W UART_STOP Number of stop bits.
This is used to select the number of stop bits per character
that the peripheral transmits and receives. If set to zero, one
stop bit is transmitted in the serial data.
If set to one and the data bits are set to 5 (LCR[1:0] set to
zero) one and a half stop bits is transmitted. Otherwise, two
stop bits are transmitted. Note that regardless of the number
of stop bits selected, the receiver checks only the first stop bit.
0 = 1 stop bit
1 = 1.5 stop bits when DLS (LCR[1:0]) is zero, else 2 stop bit
0x0
1:0 R/W UART_DLS Data Length Select.
This is used to select the number of data bits per character
that the peripheral transmits and receives. The number of bit
that may be selected areas follows:
00 = 5 bits
01 = 6 bits
10 = 7 bits
11 = 8 bits
0x0
Table 109: UART2_MCR_REG (0x50001110)
Bit Mode Symbol Description Reset
15:7 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 73 Final - January 29, 2015 v3.1
6R/W UART_SIRE SIR Mode Enable.
This is used to enable/disable the IrDA SIR Mode features as
described in "IrDA 1.0 SIR Protocol" on page 53.
0 = IrDA SIR Mode disabled
1 = IrDA SIR Mode enabled
0x0
5R/W UART_AFCE Auto Flow Control Enable.
When FIFOs are enabled and the Auto Flow Control Enable
(AFCE) bit is set, hardware Auto Flow Control is enabled via
CTS and RTS.
0 = Auto Flow Control Mode disabled
1 = Auto Flow Control Mode enabled
0x0
4R/W UART_LB LoopBack Bit.
This is used to put the UART into a diagnostic mode for test
purposes.
If operating in UART mode (SIR_MODE not active, MCR[6]
set to zero), data on the sout line is held high, while serial
data output is looped back to the sin line, internally. In this
mode all the interrupts are fully functional. Also, in loopback
mode, the modem control inputs (dsr_n, cts_n, ri_n, dcd_n)
are disconnected and the modem control outputs (dtr_n,
rts_n, out1_n, out2_n) are looped back to the inputs, inter-
nally.
If operating in infrared mode (SIR_MODE active, MCR[6] set
to one), data on the sir_out_n line is held low, while serial data
output is inverted and looped back to the sir_in line.
0x0
3R/W UART_OUT2 OUT2.
This is used to directly control the user-designated Output2
(out2_n) output. The value written to this location is inverted
and driven out on out2_n, that is:
0 = out2_n de-asserted (logic 1)
1 = out2_n asserted (logic 0)
Note that in Loopback mode (MCR[4] set to one), the out2_n
output is held inactive high while the value of this location is
internally looped back to an input.
0x0
2R/W UART_OUT1 OUT1.
This is used to directly control the user-designated Output1
(out1_n) output. The value written to this location is inverted
and driven out on out1_n, that is:
0 = out1_n de-asserted (logic 1)
1 = out1_n asserted (logic 0)
Note that in Loopback mode (MCR[4] set to one), the out1_n
output is held inactive high while the value of this location is
internally looped back to an input.
0x0
Table 109: UART2_MCR_REG (0x50001110)
Bit Mode Symbol Description Reset
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 74 Final - January 29, 2015 v3.1
1R/W UART_RTS Request to Send.
This is used to directly control the Request to Send (rts_n)
output. The Request To Send (rts_n) output is used to inform
the modem or data set that the UART is ready to exchange
data.
When Auto Flow Control is disabled (MCR[5] set to zero), the
rts_n signal is set low by programming MCR[1] (RTS) to a
high. When Auto Flow Control is enabled (MCR[5] set to one)
and FIFOs are enabled (FCR[0] set to one), the rts_n output
is controlled in the same way, but is also gated with the
receiver FIFO threshold trigger (rts_n is inactive high when
above the threshold). The rts_n signal is de-asserted when
MCR[1] is set low.
Note that in Loopback mode (MCR[4] set to one), the rts_n
output is held inactive (high) while the value of this location is
internally looped back to an input.
0x0
0--Reserved 0x0
Table 109: UART2_MCR_REG (0x50001110)
Bit Mode Symbol Description Reset
Table 110: UART2_LSR_REG (0x50001114)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7RUART_RFE Receiver FIFO Error bit.
This bit is only relevant when FIFOs are enabled (FCR[0] set
to one). This is used to indicate if there is at least one parity
error, framing error, or break indication in the FIFO.
0 = no error in RX FIFO
1 = error in RX FIFO
This bit is cleared when the LSR is read and the character
with the error is at the top of the receiver FIFO and there are
no subsequent errors in the FIFO.
0x0
6RUART_TEMT Transmitter Empty bit.
If FIFOs enabled (FCR[0] set to one), this bit is set whenever
the Transmitter Shift Register and the FIFO are both empty. If
FIFOs are disabled, this bit is set whenever the Transmitter
Holding Register and the Transmitter Shift Register are both
empty.
0x1
5RUART_THRE Transmit Holding Register Empty bit.
If THRE mode is disabled (IER[7] set to zero) and regardless
of FIFO's being implemented/enabled or not, this bit indicates
that the THR or TX FIFO is empty.
This bit is set whenever data is transferred from the THR or
TX FIFO to the transmitter shift register and no new data has
been written to the THR or TX FIFO. This also causes a
THRE Interrupt to occur, if the THRE Interrupt is enabled. If
both modes are active (IER[7] set to one and FCR[0] set to
one respectively), the functionality is switched to indicate the
transmitter FIFO is full, and no longer controls THRE inter-
rupts, which are then controlled by the FCR[5:4] threshold
setting.
0x1
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 75 Final - January 29, 2015 v3.1
4RUART_B1 Break Interrupt bit.
This is used to indicate the detection of a break sequence on
the serial input data.
If in UART mode (SIR_MODE == Disabled), it is set whenever
the serial input, sin, is held in a logic '0' state for longer than
the sum of start time + data bits + parity + stop bits.
If in infrared mode (SIR_MODE == Enabled), it is set when-
ever the serial input, sir_in, is continuously pulsed to logic '0'
for longer than the sum of start time + data bits + parity + stop
bits. A break condition on serial input causes one and only
one character, consisting of all zeros, to be received by the
UART.
In the FIFO mode, the character associated with the break
condition is carried through the FIFO and is revealed when
the character is at the top of the FIFO.
Reading the LSR clears the BI bit. In the non-FIFO mode, the
BI indication occurs immediately and persists until the LSR is
read.
0x0
3RUART_FE Framing Error bit.
This is used to indicate the occurrence of a framing error in
the receiver. A framing error occurs when the receiver does
not detect a valid STOP bit in the received data.
In the FIFO mode, since the framing error is associated with a
character received, it is revealed when the character with the
framing error is at the top of the FIFO.
When a framing error occurs, the UART tries to resynchro-
nize. It does this by assuming that the error was due to the
start bit of the next character and then continues receiving the
other bit i.e. data, and/or parity and stop. It should be noted
that the Framing Error (FE) bit (LSR[3]) is set if a break inter-
rupt has occurred, as indicated by Break Interrupt (BI) bit
(LSR[4]).
0 = no framing error
1 = framing error
Reading the LSR clears the FE bit.
0x0
2RUART_PE Parity Error bit.
This is used to indicate the occurrence of a parity error in the
receiver if the Parity Enable (PEN) bit (LCR[3]) is set.
In the FIFO mode, since the parity error is associated with a
character received, it is revealed when the character with the
parity error arrives at the top of the FIFO.
It should be noted that the Parity Error (PE) bit (LSR[2]) is set
if a break interrupt has occurred, as indicated by Break Inter-
rupt (BI) bit (LSR[4]).
0 = no parity error
1 = parity error
Reading the LSR clears the PE bit.
0x0
Table 110: UART2_LSR_REG (0x50001114)
Bit Mode Symbol Description Reset
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 76 Final - January 29, 2015 v3.1
1RUART_OE Overrun error bit.
This is used to indicate the occurrence of an overrun error.
This occurs if a new data character was received before the
previous data was read.
In the non-FIFO mode, the OE bit is set when a new character
arrives in the receiver before the previous character was read
from the RBR. When this happens, the data in the RBR is
overwritten. In the FIFO mode, an overrun error occurs when
the FIFO is full and a new character arrives at the receiver.
The data in the FIFO is retained and the data in the receive
shift register is lost.
0 = no overrun error
1 = overrun error
Reading the LSR clears the OE bit.
0x0
0RUART_DR Data Ready bit.
This is used to indicate that the receiver contains at least one
character in the RBR or the receiver FIFO.
0 = no data ready
1 = data ready
This bit is cleared when the RBR is read in non-FIFO mode,
or when the receiver FIFO is empty, in FIFO mode.
0x0
Table 110: UART2_LSR_REG (0x50001114)
Bit Mode Symbol Description Reset
Table 111: UART2_MSR_REG (0x50001118)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7RUART_DCD Data Carrier Detect.
This is used to indicate the current state of the modem control
line dcd_n. This bit is the complement of dcd_n. When the
Data Carrier Detect input (dcd_n) is asserted it is an indica-
tion that the carrier has been detected by the modem or data
set.
0 = dcd_n input is de-asserted (logic 1)
1 = dcd_n input is asserted (logic 0)
In Loopback Mode (MCR[4] set to one), DCD is the same as
MCR[3] (Out2).
0x0
6RUART_R1 Ring Indicator.
This is used to indicate the current state of the modem control
line ri_n. This bit is the complement of ri_n. When the Ring
Indicator input (ri_n) is asserted it is an indication that a tele-
phone ringing signal has been received by the modem or data
set.
0 = ri_n input is de-asserted (logic 1)
1 = ri_n input is asserted (logic 0)
In Loopback Mode (MCR[4] set to one), RI is the same as
MCR[2] (Out1).
0x0
5--Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 77 Final - January 29, 2015 v3.1
4RUART_CTS Clear to Send.
This is used to indicate the current state of the modem control
line cts_n. This bit is the complement of cts_n. When the
Clear to Send input (cts_n) is asserted it is an indication that
the modem or data set is ready to exchange data with the
UART Ctrl.
0 = cts_n input is de-asserted (logic 1)
1 = cts_n input is asserted (logic 0)
In Loopback Mode (MCR[4] = 1), CTS is the same as MCR[1]
(RTS).
0x0
3RUART_DDCD Delta Data Carrier Detect.
This is used to indicate that the modem control line dcd_n has
changed since the last time the MSR was read.
0 = no change on dcd_n since last read of MSR
1 = change on dcd_n since last read of MSR
Reading the MSR clears the DDCD bit. In Loopback Mode
(MCR[4] = 1), DDCD reflects changes on MCR[3] (Out2).
Note, if the DDCD bit is not set and the dcd_n signal is
asserted (low) and a reset occurs (software or otherwise),
then the DDCD bit is set when the reset is removed if the
dcd_n signal remains asserted.
0x0
2RUART_TERI Trailing Edge of Ring Indicator.
This is used to indicate that a change on the input ri_n (from
an active-low to an inactive-high state) has occurred since the
last time the MSR was read.
0 = no change on ri_n since last read of MSR
1 = change on ri_n since last read of MSR
Reading the MSR clears the TERI bit. In Loopback Mode
(MCR[4] = 1), TERI reflects when MCR[2] (Out1) has
changed state from a high to a low.
0x0
1--Reserved 0x0
0RUART_DCTS Delta Clear to Send.
This is used to indicate that the modem control line cts_n has
changed since the last time the MSR was read.
0 = no change on cts_n since last read of MSR
1 = change on cts_n since last read of MSR
Reading the MSR clears the DCTS bit. In Loopback Mode
(MCR[4] = 1), DCTS reflects changes on MCR[1] (RTS).
Note, if the DCTS bit is not set and the cts_n signal is
asserted (low) and a reset occurs (software or otherwise),
then the DCTS bit is set when the reset is removed if the
cts_n signal remains asserted.
0x0
Table 111: UART2_MSR_REG (0x50001118)
Bit Mode Symbol Description Reset
Table 112: UART2_SCR_REG (0x5000111C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W UART_SCRATCH_PA
D
This register is for programmers to use as a temporary stor-
age space. It has no defined purpose in the UART Ctrl.
0x0
Table 113: UART2_LPDLL_REG (0x50001120)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 78 Final - January 29, 2015 v3.1
7:0 R/W UART_LPDLL This register makes up the lower 8-bits of a 16-bit, read/write,
Low Power Divisor Latch register that contains the baud rate
divisor for the UART, which must give a baud rate of 115.2K.
This is required for SIR Low Power (minimum pulse width)
detection at the receiver. This register may be accessed only
when the DLAB bit (LCR[7]) is set.
The output low-power baud rate is equal to the serial clock
(sclk) frequency divided by sixteen times the value of the
baud rate divisor, as follows:
Low power baud rate = (serial clock frequency)/(16* divisor)
Therefore, a divisor must be selected to give a baud rate of
115.2K.
NOTE: When the Low Power Divisor Latch registers (LPDLL
and LPDLH) are set to 0, the low-power baud clock is disa-
bled and no low-power pulse detection (or any pulse detec-
tion) occurs at the receiver. Also, once the LPDLL is set, at
least eight clock cycles of the slowest UART Ctrl clock should
be allowed to pass before transmitting or receiving data.
0x0
Table 113: UART2_LPDLL_REG (0x50001120)
Bit Mode Symbol Description Reset
Table 114: UART2_LPDLH_REG (0x50001124)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W UART_LPDLH This register makes up the upper 8-bits of a 16-bit, read/write,
Low Power Divisor Latch register that contains the baud rate
divisor for the UART, which must give a baud rate of 115.2K.
This is required for SIR Low Power (minimum pulse width)
detection at the receiver. This register may be accessed only
when the DLAB bit (LCR[7]) is set.
The output low-power baud rate is equal to the serial clock
(sclk) frequency divided by sixteen times the value of the
baud rate divisor, as follows:
Low power baud rate = (serial clock frequency)/(16* divisor)
Therefore, a divisor must be selected to give a baud rate of
115.2K.
NOTE: When the Low Power Divisor Latch registers (LPDLL
and LPDLH) are set to 0, the low-power baud clock is disa-
bled and no low-power pulse detection (or any pulse detec-
tion) occurs at the receiver. Also, once the LPDLH is set, at
least eight clock cycles of the slowest UART Ctrl clock should
be allowed to pass before transmitting or receiving data.
0x0
Table 115: UART2_SRBR_STHR0_REG (0x50001130)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 79 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 115: UART2_SRBR_STHR0_REG (0x50001130)
Bit Mode Symbol Description Reset
Table 116: UART2_SRBR_STHR1_REG (0x50001134)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 80 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 116: UART2_SRBR_STHR1_REG (0x50001134)
Bit Mode Symbol Description Reset
Table 117: UART2_SRBR_STHR2_REG (0x50001138)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 81 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 117: UART2_SRBR_STHR2_REG (0x50001138)
Bit Mode Symbol Description Reset
Table 118: UART2_SRBR_STHR3_REG (0x5000113C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 82 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 118: UART2_SRBR_STHR3_REG (0x5000113C)
Bit Mode Symbol Description Reset
Table 119: UART2_SRBR_STHR4_REG (0x50001140)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 83 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 119: UART2_SRBR_STHR4_REG (0x50001140)
Bit Mode Symbol Description Reset
Table 120: UART2_SRBR_STHR5_REG (0x50001144)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 84 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 120: UART2_SRBR_STHR5_REG (0x50001144)
Bit Mode Symbol Description Reset
Table 121: UART2_SRBR_STHR6_REG (0x50001148)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 85 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 121: UART2_SRBR_STHR6_REG (0x50001148)
Bit Mode Symbol Description Reset
Table 122: UART2_SRBR_STHR7_REG (0x5000114C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 86 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 122: UART2_SRBR_STHR7_REG (0x5000114C)
Bit Mode Symbol Description Reset
Table 123: UART2_SRBR_STHR8_REG (0x50001150)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 87 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 123: UART2_SRBR_STHR8_REG (0x50001150)
Bit Mode Symbol Description Reset
Table 124: UART2_SRBR_STHR9_REG (0x50001154)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 88 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 124: UART2_SRBR_STHR9_REG (0x50001154)
Bit Mode Symbol Description Reset
Table 125: UART2_SRBR_STHR10_REG (0x50001158)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 89 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 125: UART2_SRBR_STHR10_REG (0x50001158)
Bit Mode Symbol Description Reset
Table 126: UART2_SRBR_STHR11_REG (0x5000115C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 90 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 126: UART2_SRBR_STHR11_REG (0x5000115C)
Bit Mode Symbol Description Reset
Table 127: UART2_SRBR_STHR12_REG (0x50001160)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 91 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 127: UART2_SRBR_STHR12_REG (0x50001160)
Bit Mode Symbol Description Reset
Table 128: UART2_SRBR_STHR13_REG (0x50001164)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 92 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 128: UART2_SRBR_STHR13_REG (0x50001164)
Bit Mode Symbol Description Reset
Table 129: UART2_SRBR_STHR14_REG (0x50001168)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 93 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 129: UART2_SRBR_STHR14_REG (0x50001168)
Bit Mode Symbol Description Reset
Table 130: UART2_SRBR_STHR15_REG (0x5000116C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 94 Final - January 29, 2015 v3.1
7:0 R/W SRBR_STHRX Shadow Receive Buffer Register x: This is a shadow register
for the RBR and has been allocated sixteen 32-bit locations
so as to accommodate burst accesses from the master. This
register contains the data byte received on the serial input
port (sin) in UART mode or the serial infrared input (sir_in) in
infrared mode. The data in this register is valid only if the Data
Ready (DR) bit in the Line status Register (LSR) is set. If
FIFOs are disabled (FCR[0] set to zero), the data in the RBR
must be read before the next data arrives, otherwise it will be
overwritten, resulting in an overrun error. If FIFOs are enabled
(FCR[0] set to one), this register accesses the head of the
receive FIFO. If the receive FIFO is full and this register is not
read before the next data character arrives, then the data
already in the FIFO will be preserved but any incoming data
will be lost. An overrun error will also occur. Shadow Transmit
Holding Register 0: This is a shadow register for the THR and
has been allocated sixteen 32-bit locations so as to accom-
modate burst accesses from the master. This register con-
tains data to be transmitted on the serial output port (sout) in
UART mode or the serial infrared output (sir_out_n) in infra-
red mode. Data should only be written to the THR when the
THR Empty (THRE) bit (LSR[5]) is set. If FIFO's are disabled
(FCR[0] set to zero) and THRE is set, writing a single charac-
ter to the THR clears the THRE. Any additional writes to the
THR before the THRE is set again causes the THR data to be
overwritten. If FIFO's are enabled (FCR[0] set to one) and
THRE is set, x number of characters of data may be written to
the THR before the FIFO is full. The number x (default=16) is
determined by the value of FIFO Depth that you set during
configuration. Any attempt to write data when the FIFO is full
results in the write data being lost.
0x0
Table 130: UART2_SRBR_STHR15_REG (0x5000116C)
Bit Mode Symbol Description Reset
Table 131: UART2_USR_REG (0x5000117C)
Bit Mode Symbol Description Reset
15:5 --Reserved 0x0
4RUART_RFF Receive FIFO Full.
This is used to indicate that the receive FIFO is completely
full.
0 = Receive FIFO not full
1 = Receive FIFO Full
This bit is cleared when the RX FIFO is no longer full.
0x0
3RUART_RFNE Receive FIFO Not Empty.
This is used to indicate that the receive FIFO contains one or
more entries.
0 = Receive FIFO is empty
1 = Receive FIFO is not empty
This bit is cleared when the RX FIFO is empty.
0x0
2RUART_TFE Transmit FIFO Empty.
This is used to indicate that the transmit FIFO is completely
empty.
0 = Transmit FIFO is not empty
1 = Transmit FIFO is empty
This bit is cleared when the TX FIFO is no longer empty.
0x1
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 95 Final - January 29, 2015 v3.1
1RUART_TFNF Transmit FIFO Not Full.
This is used to indicate that the transmit FIFO in not full.
0 = Transmit FIFO is full
1 = Transmit FIFO is not full
This bit is cleared when the TX FIFO is full.
0x1
0--Reserved 0x0
Table 131: UART2_USR_REG (0x5000117C)
Bit Mode Symbol Description Reset
Table 132: UART2_TFL_REG (0x50001180)
Bit Mode Symbol Description Reset
15:0 RUART_TRANSMIT_FI
FO_LEVEL
Transmit FIFO Level.
This is indicates the number of data entries in the transmit
FIFO.
0x0
Table 133: UART2_RFL_REG (0x50001184)
Bit Mode Symbol Description Reset
15:0 RUART_RECEIVE_FIF
O_LEVEL
Receive FIFO Level.
This is indicates the number of data entries in the receive
FIFO.
0x0
Table 134: UART2_SRR_REG (0x50001188)
Bit Mode Symbol Description Reset
15:3 --Reserved 0x0
2WUART_XFR XMIT FIFO Reset.
This is a shadow register for the XMIT FIFO Reset bit
(FCR[2]). This can be used to remove the burden on software
having to store previously written FCR values (which are
pretty static) just to reset the transmit FIFO. This resets the
control portion of the transmit FIFO and treats the FIFO as
empty. Note that this bit is 'self-clearing'. It is not necessary to
clear this bit.
0x0
1WUART_RFR RCVR FIFO Reset.
This is a shadow register for the RCVR FIFO Reset bit
(FCR[1]). This can be used to remove the burden on software
having to store previously written FCR values (which are
pretty static) just to reset the receive FIFO This resets the
control portion of the receive FIFO and treats the FIFO as
empty.
Note that this bit is 'self-clearing'. It is not necessary to clear
this bit.
0x0
0WUART_UR UART Reset. This asynchronously resets the UART Ctrl and
synchronously removes the reset assertion. For a two clock
implementation both pclk and sclk domains are reset.
0x0
Table 135: UART2_SRTS_REG (0x5000118C)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 96 Final - January 29, 2015 v3.1
0R/W UART_SHADOW_RE
QUEST_TO_SEND
Shadow Request to Send.
This is a shadow register for the RTS bit (MCR[1]), this can be
used to remove the burden of having to perform a read-mod-
ify-write on the MCR. This is used to directly control the
Request to Send (rts_n) output. The Request To Send (rts_n)
output is used to inform the modem or data set that the UART
Ctrl is ready to exchange data.
When Auto Flow Control is disabled (MCR[5] = 0), the rts_n
signal is set low by programming MCR[1] (RTS) to a high.
When Auto Flow Control is enabled (MCR[5] = 1) and FIFOs
are enabled (FCR[0] = 1), the rts_n output is controlled in the
same way, but is also gated with the receiver FIFO threshold
trigger (rts_n is inactive high when above the threshold).
Note that in Loopback mode (MCR[4] = 1), the rts_n output is
held inactive-high while the value of this location is internally
looped back to an input.
0x0
Table 135: UART2_SRTS_REG (0x5000118C)
Bit Mode Symbol Description Reset
Table 136: UART2_SBCR_REG (0x50001190)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0R/W UART_SHADOW_BR
EAK_CONTROL
Shadow Break Control Bit.
This is a shadow register for the Break bit (LCR[6]), this can
be used to remove the burden of having to performing a read
modify write on the LCR. This is used to cause a break condi-
tion to be transmitted to the receiving device.
If set to one the serial output is forced to the spacing (logic 0)
state. When not in Loopback Mode, as determined by
MCR[4], the sout line is forced low until the Break bit is
cleared.
If SIR_MODE active (MCR[6] = 1) the sir_out_n line is contin-
uously pulsed. When in Loopback Mode, the break condition
is internally looped back to the receiver.
0x0
Table 137: UART2_SDMAM_REG (0x50001194)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0R/W UART_SHADOW_DM
A_MODE
Shadow DMA Mode.
This is a shadow register for the DMA mode bit (FCR[3]). This
can be used to remove the burden of having to store the pre-
viously written value to the FCR in memory and having to
mask this value so that only the DMA Mode bit gets updated.
This determines the DMA signalling mode used for the
dma_tx_req_n and dma_rx_req_n output signals.
0 = mode 0
1 = mode 1
0x0
Table 138: UART2_SFE_REG (0x50001198)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 97 Final - January 29, 2015 v3.1
0R/W UART_SHADOW_FIF
O_ENABLE
Shadow FIFO Enable.
This is a shadow register for the FIFO enable bit (FCR[0]).
This can be used to remove the burden of having to store the
previously written value to the FCR in memory and having to
mask this value so that only the FIFO enable bit gets
updated.This enables/disables the transmit (XMIT) and
receive (RCVR) FIFOs. If this bit is set to zero (disabled) after
being enabled then both the XMIT and RCVR controller por-
tion of FIFOs are reset.
0x0
Table 138: UART2_SFE_REG (0x50001198)
Bit Mode Symbol Description Reset
Table 139: UART2_SRT_REG (0x5000119C)
Bit Mode Symbol Description Reset
15:2 --Reserved 0x0
1:0 R/W UART_SHADOW_RC
VR_TRIGGER
Shadow RCVR Trigger.
This is a shadow register for the RCVR trigger bits (FCR[7:6]).
This can be used to remove the burden of having to store the
previously written value to the FCR in memory and having to
mask this value so that only the RCVR trigger bit gets
updated.
This is used to select the trigger level in the receiver FIFO at
which the Received Data Available Interrupt is generated. It
also determines when the dma_rx_req_n signal is asserted
when DMA Mode (FCR[3]) = 1. The following trigger levels
are supported:
00 = 1 character in the FIFO
01 = FIFO ¼ full
10 = FIFO ½ full
11 = FIFO 2 less than full
0x0
Table 140: UART2_STET_REG (0x500011A0)
Bit Mode Symbol Description Reset
15:2 --Reserved 0x0
1:0 R/W UART_SHADOW_TX
_EMPTY_TRIGGER
Shadow TX Empty Trigger.
This is a shadow register for the TX empty trigger bits
(FCR[5:4]). This can be used to remove the burden of having
to store the previously written value to the FCR in memory
and having to mask this value so that only the TX empty trig-
ger bit gets updated.
This is used to select the empty threshold level at which the
THRE Interrupts are generated when the mode is active. The
following trigger levels are supported:
00 = FIFO empty
01 = 2 characters in the FIFO
10 = FIFO ¼ full
11 = FIFO ½ full
0x0
Table 141: UART2_HTX_REG (0x500011A4)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 98 Final - January 29, 2015 v3.1
0R/W UART_HALT_TX This register is use to halt transmissions for testing, so that
the transmit FIFO can be filled by the master when FIFOs are
implemented and enabled.
0 = Halt TX disabled
1 = Halt TX enabled
Note, if FIFOs are implemented and not enabled, the setting
of the halt TX register has no effect on operation.
0x0
Table 141: UART2_HTX_REG (0x500011A4)
Bit Mode Symbol Description Reset
Table 142: UART2_CPR_REG (0x500011F4)
Bit Mode Symbol Description Reset
15:0 RCPR Component Parameter Register 0x0
Table 143: UART2_UCV_REG (0x500011F8)
Bit Mode Symbol Description Reset
15:0 RUCV Component Version 0x333038
2A
Table 144: UART2_CTR_REG (0x500011FC)
Bit Mode Symbol Description Reset
15:0 RCTR Component Type Register 0x445701
10
Table 145: SPI_CTRL_REG (0x50001200)
Bit Mode Symbol Description Reset
15 R/W SPI_EN_CTRL 0 = SPI_EN pin disabled in slave mode. Pin SPI_EN is don't
care.
1 = SPI_EN pin enabled in slave mode.
0x0
14 R/W SPI_MINT 0 = Disable SPI_INT_BIT to ICU
1 = Enable SPI_INT_BIT to ICU.
Note that the SPI_INT interrupt is shared with AD_INT inter-
rupt
0x0
13 RSPI_INT_BIT 0 = RX Register or FIFO is empty.
1 = SPI interrupt. Data has been transmitted and received-
Must be reset by SW by writing to SPI_CLEAR_INT_REG.
0x0
12 RSPI_DI Returns the actual value of pin SPI_DIN (delayed with two
internal SPI clock cycles)
0x0
11 RSPI_TXH 0 = TX-FIFO is not full, data can be written.
1 = TX-FIFO is full, data can not be written.
0x0
10 R/W SPI_FORCE_DO 0 = normal operation
1 = Force SPIDO output level to value of SPI_DO.
0x0
9R/W SPI_RST 0 = normal operation
1 = Reset SPI. Same function as SPI_ON except that internal
clock remain active.
0x0
8:7 R/W SPI_WORD 00 = 8 bits mode, only SPI_RX_TX_REG0 used
01 = 16 bit mode, only SPI_RX_TX_REG0 used
10 = 32 bits mode, SPI_RX_TX_REG0 & SPI_RX_TX_REG1
used
11 = 9 bits mode. Only valid in master mode.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 99 Final - January 29, 2015 v3.1
6R/W SPI_SMN Master/slave mode
0 = Master,
1 = Slave(SPI1 only)
0x0
5R/W SPI_DO Pin SPI_DO output level when SPI is idle or when
SPI_FORCE_DO=1
0x0
4:3 R/W SPI_CLK Select SPI_CLK clock frequency in master mode:00 = (XTAL)
/ (CLK_PER_REG *8)
01 = (XTAL) / (CLK_PER_REG *4)
10 = (XTAL) / (CLK_PER_REG *2)
11 = (XTAL) / (CLK_PER_REG *14)
0x0
2R/W SPI_POL Select SPI_CLK polarity.
0 = SPI_CLK is initially low.
1 = SPI_CLK is initially high.
0x0
1R/W SPI_PHA Select SPI_CLK phase. See functional timing diagrams in SPI
chapter
0x0
0R/W SPI_ON 0 = SPI Module switched off (power saving). Everything is
reset except SPI_CTRL_REG0 and SPI_CTRL_REG1. When
this bit is cleared the SPI will remain active in master mode
until the shift register and holding register are both empty.
1 = SPI Module switched on. Should only be set after all con-
trol bits have their desired values. So two writes are needed!
0x0
Table 145: SPI_CTRL_REG (0x50001200)
Bit Mode Symbol Description Reset
Table 146: SPI_RX_TX_REG0 (0x50001202)
Bit Mode Symbol Description Reset
15:0 R0/W SPI_DATA0 Write: SPI_TX_REG0 output register 0 (TX-FIFO)
Read: SPI_RX_REG0 input register 0 (RX-FIFO)
In 8 or 9 bits mode bits 15 to 8 are not used, they contain old
data.
0x0
Table 147: SPI_RX_TX_REG1 (0x50001204)
Bit Mode Symbol Description Reset
15:0 R0/W SPI_DATA1 Write: SPI_TX_REG1 output register 1 (MSB's of TX-FIFO)
Read: SPI_RX_REG1 input register 1 (MSB's of RX-FIFO)
In 8 or 9 or 16 bits mode bits this register is not used.
0x0
Table 148: SPI_CLEAR_INT_REG (0x50001206)
Bit Mode Symbol Description Reset
15:0 R0/W SPI_CLEAR_INT Writing any value to this register will clear the
SPI_CTRL_REG[SPI_INT_BIT]
Reading returns 0.
0x0
Table 149: SPI_CTRL_REG1 (0x50001208)
Bit Mode Symbol Description Reset
15:5 --Reserved 0x0
4R/W SPI_9BIT_VAL Determines the value of the first bit in 9 bits SPI mode. 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 100 Final - January 29, 2015 v3.1
3RSPI_BUSY 0 = The SPI is not busy with a transfer. This means that either
no TX-data is available or that the transfers have been sus-
pended due to a full RX-FIFO. The
SPIx_CTRL_REG0[SPI_INT_BIT] can be used to distinguish
between these situations.
1 = The SPI is busy with a transfer.
0x0
2R/W SPI_PRIORITY 0 = The SPI has low priority, the DMA request signals are
reset after the corresponding acknowledge.
1 = The SPI has high priority, DMA request signals remain
active until the FIFOS are filled/emptied, so the DMA holds
the AHB bus.
0x0
1:0 R/W SPI_FIFO_MODE 0: TX-FIFO and RX-FIFO used (Bidirectional mode).
1: RX-FIFO used (Read Only Mode) TX-FIFO single depth,
no flow control
2: TX-FIFO used (Write Only Mode), RX-FIFO single depth,
no flow control
3: No FIFOs used (backwards compatible mode)
0x3
Table 149: SPI_CTRL_REG1 (0x50001208)
Bit Mode Symbol Description Reset
Table 150: I2C_CON_REG (0x50001300)
Bit Mode Symbol Description Reset
15:7 --Reserved 0x0
6R/W I2C_SLAVE_DISABLE Slave enabled or disabled after reset is applied, which means
software does not have to configure the slave.
0=slave is enabled
1=slave is disabled
Software should ensure that if this bit is written with '0', then
bit 0 should also be written with a '0'.
0x1
5R/W I2C_RESTART_EN Determines whether RESTART conditions may be sent when
acting as a master
0= disable
1=enable
0x1
4R/W I2C_10BITADDR_MA
STER
Controls whether the controller starts its transfers in 7- or 10-
bit addressing mode when acting as a master.
0= 7-bit addressing
1= 10-bit addressing
0x1
3R/W I2C_10BITADDR_SLA
VE
When acting as a slave, this bit controls whether the controller
responds to 7- or 10-bit addresses.
0= 7-bit addressing
1= 10-bit addressing
0x1
2:1 R/W I2C_SPEED These bits control at which speed the controller operates.
1= standard mode (100 kbit/s)
2= fast mode (400 kbit/s)
0x2
0R/W I2C_MASTER_MODE This bit controls whether the controller master is enabled.
0= master disabled
1= master enabled
Software should ensure that if this bit is written with '1' then bit
6 should also be written with a '1'.
0x1
Table 151: I2C_TAR_REG (0x50001304)
Bit Mode Symbol Description Reset
15:12 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 101 Final - January 29, 2015 v3.1
11 R/W SPECIAL This bit indicates whether software performs a General Call or
START BYTE command.
0: ignore bit 10 GC_OR_START and use IC_TAR normally
1: perform special I2C command as specified in
GC_OR_START
bit
0x0
10 R/W GC_OR_START If bit 11 (SPECIAL) is set to 1, then this bit indicates whether a
General Call or START byte command is to be performed by
the controller.
0: General Call Address - after issuing a General Call, only
writes may be performed. Attempting to issue a read com-
mand results in setting bit 6 (TX_ABRT) of the
IC_RAW_INTR_STAT register. The controller remains in Gen-
eral Call mode until the SPECIAL bit value (bit 11) is cleared.
1: START BYTE
0x0
9:0 R/W IC_TAR This is the target address for any master transaction. When
transmitting a General Call, these bits are ignored. To gener-
ate a START BYTE, the CPU needs to write only once into
these bits.
Note: If the IC_TAR and IC_SAR are the same, loopback
exists but the FIFOs are shared between master and slave,
so full loopback is not feasible. Only one direction loopback
mode is supported (simplex), not duplex. A master cannot
transmit to itself; it can transmit to only a slave
0x55
Table 151: I2C_TAR_REG (0x50001304)
Bit Mode Symbol Description Reset
Table 152: I2C_SAR_REG (0x50001308)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:0 R/W IC_SAR The IC_SAR holds the slave address when the I2C is operat-
ing as a slave. For 7-bit addressing, only IC_SAR[6:0] is
used. This register can be written only when the I2C interface
is disabled, which corresponds to the IC_ENABLE register
being set to 0. Writes at other times have no effect.
0x55
Table 153: I2C_DATA_CMD_REG (0x50001310)
Bit Mode Symbol Description Reset
15:9 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 102 Final - January 29, 2015 v3.1
8R/W CMD This bit controls whether a read or a write is performed. This
bit does not control the direction when the I2C Ctrl acts as a
slave. It controls only the direction when it acts as a master.
1 = Read
0 = Write
When a command is entered in the TX FIFO, this bit distin-
guishes the write and read commands. In slave-receiver
mode, this bit is a "don't care" because writes to this register
are not required. In slave-transmitter mode, a "0" indicates
that CPU data is to be transmitted and as DAT or
IC_DATA_CMD[7:0]. When programming this bit, you should
remember the following: attempting to perform a read opera-
tion after a General Call command has been sent results in a
TX_ABRT interrupt (bit 6 of the
I2C_RAW_INTR_STAT_REG), unless bit 11 (SPECIAL) in the
I2C_TAR register has been cleared.
If a "1" is written to this bit after receiving a RD_REQ interrupt,
then a TX_ABRT interrupt occurs.
NOTE: It is possible that while attempting a master I2C read
transfer on the controller, a RD_REQ interrupt may have
occurred simultaneously due to a remote I2C master address-
ing the controller. In this type of scenario, it ignores the
I2C_DATA_CMD write, generates a TX_ABRT interrupt, and
waits to service the RD_REQ interrupt
0x0
7:0 R/W DAT This register contains the data to be transmitted or received
on the I2C bus. If you are writing to this register and want to
perform a read, bits 7:0 (DAT) are ignored by the controller.
However, when you read this register, these bits return the
value of data received on the controller's interface.
0x0
Table 153: I2C_DATA_CMD_REG (0x50001310)
Bit Mode Symbol Description Reset
Table 154: I2C_SS_SCL_HCNT_REG (0x50001314)
Bit Mode Symbol Description Reset
15:0 R/W IC_SS_SCL_HCNT This register must be set before any I2C bus transaction can
take place to ensure proper I/O timing. This register sets the
SCL clock high-period count for standard speed. This register
can be written only when the I2C interface is disabled which
corresponds to the IC_ENABLE register being set to 0. Writes
at other
times have no effect.
The minimum valid value is 6; hardware prevents values less
than this being written, and if attempted results in 6 being set.
NOTE: This register must not be programmed to a value
higher than 65525, because the controller uses a 16-bit coun-
ter to flag an I2C bus idle condition when this counter reaches
a value of IC_SS_SCL_HCNT + 10.
0x48
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 103 Final - January 29, 2015 v3.1
Table 155: I2C_SS_SCL_LCNT_REG (0x50001318)
Bit Mode Symbol Description Reset
15:0 R/W IC_SS_SCL_LCNT This register must be set before any I2C bus transaction can
take place to ensure proper I/O timing. This register sets the
SCL clock low period count for standard speed.
This register can be written only when the I2C interface is dis-
abled which corresponds to the I2C_ENABLE register being
set to 0. Writes at other times have no effect.
The minimum valid value is 8; hardware prevents values less
than this being written, and if attempted, results in 8 being set.
0x4F
Table 156: I2C_FS_SCL_HCNT_REG (0x5000131C)
Bit Mode Symbol Description Reset
15:0 R/W IC_FS_SCL_HCNT This register must be set before any I2C bus transaction can
take place to ensure proper I/O timing. This register sets the
SCL clock high-period count for fast speed. It is used in high-
speed mode to send the Master Code and START BYTE or
General CALL. This register can be written only when the I2C
interface is disabled, which corresponds to the I2C_ENABLE
register being set to 0. Writes at other times have no effect.
The minimum valid value is 6; hardware prevents values less
than this being written, and if attempted results in 6 being set.
0x8
Table 157: I2C_FS_SCL_LCNT_REG (0x50001320)
Bit Mode Symbol Description Reset
15:0 R/W IC_FS_SCL_LCNT This register must be set before any I2C bus transaction can
take place to ensure proper I/O timing. This register sets the
SCL clock low-period count for fast speed. It is used in high-
speed mode to send the Master Code and START BYTE or
General CALL. This register can be written only when the I2C
interface is disabled, which corresponds to the I2C_ENABLE
register being set to 0. Writes at other times have no effect.
The minimum valid value is 8; hardware prevents values less
than this being written, and if attempted results in 8 being set.
For designs with APB_DATA_WIDTH = 8 the order of pro-
gramming is important to ensure the correct operation of the
controller. The lower byte must be programmed first. Then the
upper byte is programmed.
0x17
Table 158: I2C_INTR_STAT_REG (0x5000132C)
Bit Mode Symbol Description Reset
15:12 --Reserved 0x0
11 RR_GEN_CALL Set only when a General Call address is received and it is
acknowledged. It stays set until it is cleared either by disa-
bling controller or when the CPU reads bit 0 of the
I2C_CLR_GEN_CALL register. The controller stores the
received data in the Rx buffer.
0x0
10 RR_START_DET Indicates whether a START or RESTART condition has
occurred on the I2C interface regardless of whether controller
is operating in slave or master mode.
0x0
9RR_STOP_DET Indicates whether a STOP condition has occurred on the I2C
interface regardless of whether controller is operating in slave
or master mode.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 104 Final - January 29, 2015 v3.1
8RR_ACTIVITY This bit captures I2C Ctrl activity and stays set until it is
cleared. There are four ways to clear it:
=> Disabling the I2C Ctrl
=> Reading the IC_CLR_ACTIVITY register
=> Reading the IC_CLR_INTR register
=> System reset
Once this bit is set, it stays set unless one of the four methods
is used to clear it. Even if the controller module is idle, this bit
remains set until cleared, indicating that there was activity on
the bus.
0x0
7RR_RX_DONE When the controller is acting as a slave-transmitter, this bit is
set to 1 if the master does not acknowledge a transmitted
byte. This occurs on the last byte of the transmission, indicat-
ing that the transmission is done.
0x0
6RR_TX_ABRT This bit indicates if the controller, as an I2C transmitter, is
unable to complete the intended actions on the contents of
the transmit FIFO. This situation can occur both as an I2C
master or an I2C slave, and is referred to as a "transmit
abort".
When this bit is set to 1, the I2C_TX_ABRT_SOURCE regis-
ter indicates the reason why the transmit abort takes places.
NOTE: The controller flushes/resets/empties the TX FIFO
whenever this bit is set. The TX FIFO remains in this flushed
state until the register I2C_CLR_TX_ABRT is read. Once this
read is performed, the TX FIFO is then ready to accept more
data bytes from the APB interface.
0x0
5RR_RD_REQ This bit is set to 1 when the controller is acting as a slave and
another I2C master is attempting to read data from the con-
troller. The controller holds the I2C bus in a wait state
(SCL=0) until this interrupt is serviced, which means that the
slave has been addressed by a remote master that is asking
for data to be transferred. The processor must respond to this
interrupt and then write the requested data to the
I2C_DATA_CMD register. This bit is set to 0 just after the pro-
cessor reads the I2C_CLR_RD_REQ register
0x0
4RR_TX_EMPTY This bit is set to 1 when the transmit buffer is at or below the
threshold value set in the I2C_TX_TL register. It is automati-
cally cleared by hardware when the buffer level goes above
the threshold. When the IC_ENABLE bit 0 is 0, the TX FIFO is
flushed and held in reset. There the TX FIFO looks like it has
no data within it, so this bit is set to 1, provided there is activity
in the master or slave state machines. When there is no
longer activity, then with ic_en=0, this bit is set to 0.
0x0
3RR_TX_OVER Set during transmit if the transmit buffer is filled to 32 and the
processor attempts to issue another I2C command by writing
to the IC_DATA_CMD register. When the module is disabled,
this bit keeps its level until the master or slave state machines
go into idle, and when ic_en goes to 0, this interrupt is cleared
0x0
2RR_RX_FULL Set when the receive buffer reaches or goes above the
RX_TL threshold in the I2C_RX_TL register. It is automati-
cally cleared by hardware when buffer level goes below the
threshold. If the module is disabled (I2C_ENABLE[0]=0), the
RX FIFO is flushed and held in reset; therefore the RX FIFO
is not full. So this bit is cleared once the I2C_ENABLE bit 0 is
programmed with a 0, regardless of the activity that contin-
ues.
0x0
Table 158: I2C_INTR_STAT_REG (0x5000132C)
Bit Mode Symbol Description Reset
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 105 Final - January 29, 2015 v3.1
1RR_RX_OVER Set if the receive buffer is completely filled to 32 and an addi-
tional byte is received from an external I2C device. The con-
troller acknowledges this, but any data bytes received after
the FIFO is full are lost. If the module is disabled
(I2C_ENABLE[0]=0), this bit keeps its level until the master or
slave state machines go into idle, and when ic_en goes to 0,
this interrupt is cleared.
0x0
0RR_RX_UNDER Set if the processor attempts to read the receive buffer when
it is empty by reading from the IC_DATA_CMD register. If the
module is disabled (I2C_ENABLE[0]=0), this bit keeps its
level until the master or slave state machines go into idle, and
when ic_en goes to 0, this interrupt is cleared.
0x0
Table 158: I2C_INTR_STAT_REG (0x5000132C)
Bit Mode Symbol Description Reset
Table 159: I2C_INTR_MASK_REG (0x50001330)
Bit Mode Symbol Description Reset
15:12 --Reserved 0x0
11 R/W M_GEN_CALL These bits mask their corresponding interrupt status bits in
the I2C_INTR_STAT register.
0x1
10 R/W M_START_DET These bits mask their corresponding interrupt status bits in
the I2C_INTR_STAT register.
0x0
9R/W M_STOP_DET These bits mask their corresponding interrupt status bits in
the I2C_INTR_STAT register.
0x0
8R/W M_ACTIVITY These bits mask their corresponding interrupt status bits in
the I2C_INTR_STAT register.
0x0
7R/W M_RX_DONE These bits mask their corresponding interrupt status bits in
the I2C_INTR_STAT register.
0x1
6R/W M_TX_ABRT These bits mask their corresponding interrupt status bits in
the I2C_INTR_STAT register.
0x1
5R/W M_RD_REQ These bits mask their corresponding interrupt status bits in
the I2C_INTR_STAT register.
0x1
4R/W M_TX_EMPTY These bits mask their corresponding interrupt status bits in
the I2C_INTR_STAT register.
0x1
3R/W M_TX_OVER These bits mask their corresponding interrupt status bits in
the I2C_INTR_STAT register.
0x1
2R/W M_RX_FULL These bits mask their corresponding interrupt status bits in
the I2C_INTR_STAT register.
0x1
1R/W M_RX_OVER These bits mask their corresponding interrupt status bits in
the I2C_INTR_STAT register.
0x1
0R/W M_RX_UNDER These bits mask their corresponding interrupt status bits in
the I2C_INTR_STAT register.
0x1
Table 160: I2C_RAW_INTR_STAT_REG (0x50001334)
Bit Mode Symbol Description Reset
15:12 --Reserved 0x0
11 RGEN_CALL Set only when a General Call address is received and it is
acknowledged. It stays set until it is cleared either by disa-
bling controller or when the CPU reads bit 0 of the
I2C_CLR_GEN_CALL register. I2C Ctrl stores the received
data in the Rx buffer.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 106 Final - January 29, 2015 v3.1
10 RSTART_DET Indicates whether a START or RESTART condition has
occurred on the I2C interface regardless of whether controller
is operating in slave or master mode.
0x0
9RSTOP_DET Indicates whether a STOP condition has occurred on the I2C
interface regardless of whether controller is operating in slave
or master mode.
0x0
8RACTIVITY This bit captures I2C Ctrl activity and stays set until it is
cleared. There are four ways to clear it:
=> Disabling the I2C Ctrl
=> Reading the IC_CLR_ACTIVITY register
=> Reading the IC_CLR_INTR register
=> System reset
Once this bit is set, it stays set unless one of the four methods
is used to clear it. Even if the controller module is idle, this bit
remains set until cleared, indicating that there was activity on
the bus.
0x0
7RRX_DONE When the controller is acting as a slave-transmitter, this bit is
set to 1 if the master does not acknowledge a transmitted
byte. This occurs on the last byte of the transmission, indicat-
ing that the transmission is done.
0x0
6RTX_ABRT This bit indicates if the controller, as an I2C transmitter, is
unable to complete the intended actions on the contents of
the transmit FIFO. This situation can occur both as an I2C
master or an I2C slave, and is referred to as a "transmit
abort".
When this bit is set to 1, the I2C_TX_ABRT_SOURCE regis-
ter indicates the reason why the transmit abort takes places.
NOTE: The controller flushes/resets/empties the TX FIFO
whenever this bit is set. The TX FIFO remains in this flushed
state until the register I2C_CLR_TX_ABRT is read. Once this
read is performed, the TX FIFO is then ready to accept more
data bytes from the APB interface.
0x0
5RRD_REQ This bit is set to 1 when I2C Ctrl is acting as a slave and
another I2C master is attempting to read data from the con-
troller. The controller holds the I2C bus in a wait state
(SCL=0) until this interrupt is serviced, which means that the
slave has been addressed by a remote master that is asking
for data to be transferred. The processor must respond to this
interrupt and then write the requested data to the
I2C_DATA_CMD register. This bit is set to 0 just after the pro-
cessor reads the I2C_CLR_RD_REQ register
0x0
4RTX_EMPTY This bit is set to 1 when the transmit buffer is at or below the
threshold value set in the I2C_TX_TL register. It is automati-
cally cleared by hardware when the buffer level goes above
the threshold. When the IC_ENABLE bit 0 is 0, the TX FIFO is
flushed and held in reset. There the TX FIFO looks like it has
no data within it, so this bit is set to 1, provided there is activity
in the master or slave state machines. When there is no
longer activity, then with ic_en=0, this bit is set to 0.
0x0
3RTX_OVER Set during transmit if the transmit buffer is filled to 32 and the
processor attempts to issue another I2C command by writing
to the IC_DATA_CMD register. When the module is disabled,
this bit keeps its level until the master or slave state machines
go into idle, and when ic_en goes to 0, this interrupt is cleared
0x0
Table 160: I2C_RAW_INTR_STAT_REG (0x50001334)
Bit Mode Symbol Description Reset
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 107 Final - January 29, 2015 v3.1
2RRX_FULL Set when the receive buffer reaches or goes above the
RX_TL threshold in the I2C_RX_TL register. It is automati-
cally cleared by hardware when buffer level goes below the
threshold. If the module is disabled (I2C_ENABLE[0]=0), the
RX FIFO is flushed and held in reset; therefore the RX FIFO
is not full. So this bit is cleared once the I2C_ENABLE bit 0 is
programmed with a 0, regardless of the activity that contin-
ues.
0x0
1RRX_OVER Set if the receive buffer is completely filled to 32 and an addi-
tional byte is received from an external I2C device. The con-
troller acknowledges this, but any data bytes received after
the FIFO is full are lost. If the module is disabled
(I2C_ENABLE[0]=0), this bit keeps its level until the master or
slave state machines go into idle, and when ic_en goes to 0,
this interrupt is cleared.
0x0
0RRX_UNDER Set if the processor attempts to read the receive buffer when
it is empty by reading from the IC_DATA_CMD register. If the
module is disabled (I2C_ENABLE[0]=0), this bit keeps its
level until the master or slave state machines go into idle, and
when ic_en goes to 0, this interrupt is cleared.
0x0
Table 160: I2C_RAW_INTR_STAT_REG (0x50001334)
Bit Mode Symbol Description Reset
Table 161: I2C_RX_TL_REG (0x50001338)
Bit Mode Symbol Description Reset
15:5 --Reserved 0x0
4:0 R/W RX_TL Receive FIFO Threshold Level Controls the level of entries
(or above) that triggers the RX_FULL interrupt (bit 2 in
I2C_RAW_INTR_STAT register). The valid range is 0-31, with
the additional restriction that hardware does not allow this
value to be set to a value larger than the depth of the buffer. If
an attempt is made to do that, the actual value set will be the
maximum depth of the buffer. A value of 0 sets the threshold
for 1 entry, and a value of 31 sets the threshold for 32 entries.
0x0
Table 162: I2C_TX_TL_REG (0x5000133C)
Bit Mode Symbol Description Reset
15:5 --Reserved 0x0
4:0 R/W RX_TL Transmit FIFO Threshold Level Controls the level of entries
(or below) that trigger the TX_EMPTY interrupt (bit 4 in
I2C_RAW_INTR_STAT register). The valid range is 0-31, with
the additional restriction that it may not be set to value larger
than the depth of the buffer. If an attempt is made to do that,
the actual value set will be the maximum depth of the buffer. A
value of 0 sets the threshold for 0 entries, and a value of 31
sets the threshold for 32 entries..
0x0
Table 163: I2C_CLR_INTR_REG (0x50001340)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 108 Final - January 29, 2015 v3.1
0RCLR_INTR Read this register to clear the combined interrupt, all individ-
ual interrupts, and the I2C_TX_ABRT_SOURCE register.
This bit does not clear hardware clearable interrupts but soft-
ware clearable interrupts. Refer to Bit 9 of the
I2C_TX_ABRT_SOURCE register for an exception to clearing
I2C_TX_ABRT_SOURCE
0x0
Table 163: I2C_CLR_INTR_REG (0x50001340)
Bit Mode Symbol Description Reset
Table 164: I2C_CLR_RX_UNDER_REG (0x50001344)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0RCLR_RX_UNDER Read this register to clear the RX_UNDER interrupt (bit 0) of
the
I2C_RAW_INTR_STAT register.
0x0
Table 165: I2C_CLR_RX_OVER_REG (0x50001348)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0RCLR_RX_OVER Read this register to clear the RX_OVER interrupt (bit 1) of
the
I2C_RAW_INTR_STAT register.
0x0
Table 166: I2C_CLR_TX_OVER_REG (0x5000134C)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0RCLR_TX_OVER Read this register to clear the TX_OVER interrupt (bit 3) of
the I2C_RAW_INTR_STAT register.
0x0
Table 167: I2C_CLR_RD_REQ_REG (0x50001350)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0RCLR_RD_REQ Read this register to clear the RD_REQ interrupt (bit 5) of the
I2C_RAW_INTR_STAT register.
0x0
Table 168: I2C_CLR_TX_ABRT_REG (0x50001354)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0RCLR_TX_ABRT Read this register to clear the TX_ABRT interrupt (bit 6) of the
IC_RAW_INTR_STAT register, and the
I2C_TX_ABRT_SOURCE register. This also releases the TX
FIFO from the flushed/reset state, allowing more writes to the
TX FIFO. Refer to Bit 9 of the I2C_TX_ABRT_SOURCE reg-
ister for an exception to clearing IC_TX_ABRT_SOURCE.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 109 Final - January 29, 2015 v3.1
Table 169: I2C_CLR_RX_DONE_REG (0x50001358)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0RCLR_RX_DONE Read this register to clear the RX_DONE interrupt (bit 7) of
the
I2C_RAW_INTR_STAT register.
0x0
Table 170: I2C_CLR_ACTIVITY_REG (0x5000135C)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0RCLR_ACTIVITY Reading this register clears the ACTIVITY interrupt if the I2C
is not active anymore. If the I2C module is still active on the
bus, the ACTIVITY interrupt bit continues to be set. It is auto-
matically cleared by hardware if the module is disabled and if
there is no further activity on the bus. The value read from this
register to get status of the ACTIVITY interrupt (bit 8) of the
IC_RAW_INTR_STAT register
0x0
Table 171: I2C_CLR_STOP_DET_REG (0x50001360)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0RCLR_ACTIVITY Reading this register clears the ACTIVITY interrupt if the I2C
is not active anymore. If the I2C module is still active on the
bus, the ACTIVITY interrupt bit continues to be set. It is auto-
matically cleared by hardware if the module is disabled and if
there is no further activity on the bus. The value read from this
register to get status of the ACTIVITY interrupt (bit 8) of the
IC_RAW_INTR_STAT register.
0x0
Table 172: I2C_CLR_START_DET_REG (0x50001364)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0RCLR_START_DET Read this register to clear the START_DET interrupt (bit 10)
of the IC_RAW_INTR_STAT register.
0x0
Table 173: I2C_CLR_GEN_CALL_REG (0x50001368)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0RCLR_GEN_CALL Read this register to clear the GEN_CALL interrupt (bit 11) of
I2C_RAW_INTR_STAT register.
0x0
Table 174: I2C_ENABLE_REG (0x5000136C)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 110 Final - January 29, 2015 v3.1
0R/W CTRL_ENABLE Controls whether the controller is enabled.
0: Disables the controller (TX and RX FIFOs are held in an
erased state)
1: Enables the controller
Software can disable the controller while it is active. However,
it is important that care be taken to ensure that the controller
is disabled properly. When the controller is disabled, the fol-
lowing occurs:
* The TX FIFO and RX FIFO get flushed.
* Status bits in the IC_INTR_STAT register are still active until
the controller goes into IDLE state.
If the module is transmitting, it stops as well as deletes the
contents of the transmit buffer after the current transfer is
complete. If the module is receiving, the controller stops the
current transfer at the end of the current byte and does not
acknowledge the transfer.
There is a two ic_clk delay when enabling or disabling the
controller
0x0
Table 174: I2C_ENABLE_REG (0x5000136C)
Bit Mode Symbol Description Reset
Table 175: I2C_STATUS_REG (0x50001370)
Bit Mode Symbol Description Reset
15:7 --Reserved 0x0
6RSLV_ACTIVITY Slave FSM Activity Status. When the Slave Finite State
Machine (FSM) is not in the IDLE state, this bit is set.
0: Slave FSM is in IDLE state so the Slave part of the control-
ler is not Active
1: Slave FSM is not in IDLE state so the Slave part of the con-
troller is Active
0x0
5RMST_ACTIVITY Master FSM Activity Status. When the Master Finite State
Machine (FSM) is not in the IDLE state, this bit is set.
0: Master FSM is in IDLE state so the Master part of the con-
troller is not Active
1: Master FSM is not in IDLE state so the Master part of the
controller is Active
0x0
4RRFF Receive FIFO Completely Full. When the receive FIFO is
completely full, this bit is set. When the receive FIFO contains
one or more empty location, this bit is cleared.
0: Receive FIFO is not full
1: Receive FIFO is full
0x0
3RRFNE Receive FIFO Not Empty. This bit is set when the receive
FIFO contains one or more entries; it is cleared when the
receive FIFO is empty.
0: Receive FIFO is empty
1: Receive FIFO is not empty
0x0
2RTFE Transmit FIFO Completely Empty. When the transmit FIFO is
completely empty, this bit is set. When it contains one or more
valid entries, this bit is cleared. This bit field does not request
an interrupt.
0: Transmit FIFO is not empty
1: Transmit FIFO is empty
0x1
1RTFNF Transmit FIFO Not Full. Set when the transmit FIFO contains
one or more empty locations, and is cleared when the FIFO is
full.
0: Transmit FIFO is full
1: Transmit FIFO is not full
0x1
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 111 Final - January 29, 2015 v3.1
0RI2C_ACTIVITY I2C Activity Status. 0x0
Table 175: I2C_STATUS_REG (0x50001370)
Bit Mode Symbol Description Reset
Table 176: I2C_TXFLR_REG (0x50001374)
Bit Mode Symbol Description Reset
15:6 --Reserved 0x0
5:0 RTXFLR Transmit FIFO Level. Contains the number of valid data
entries in the transmit FIFO. Size is constrained by the
TXFLR value
0x0
Table 177: I2C_RXFLR_REG (0x50001378)
Bit Mode Symbol Description Reset
15:6 --Reserved 0x0
5:0 RRXFLR Receive FIFO Level. Contains the number of valid data
entries in the receive FIFO. Size is constrained by the RXFLR
value
0x0
Table 178: I2C_SDA_HOLD_REG (0x5000137C)
Bit Mode Symbol Description Reset
15:0 R/W IC_SDA_HOLD SDA Hold time 0x1
Table 179: I2C_TX_ABRT_SOURCE_REG (0x50001380)
Bit Mode Symbol Description Reset
15 RABRT_SLVRD_INTX 1: When the processor side responds to a slave mode
request for data to be transmitted to a remote master and
user writes a 1 in CMD (bit 8) of 2IC_DATA_CMD register
0x0
14 RABRT_SLV_ARBLOS
T
1: Slave lost the bus while transmitting data to a remote mas-
ter.
I2C_TX_ABRT_SOURCE[12] is set at the same time. Note:
Even though the slave never "owns" the bus, something could
go wrong on the bus. This is a fail safe check. For instance,
during a data transmission at the low-to-high transition of
SCL, if what is on the data bus is not what is supposed to be
transmitted, then the controller no longer own the bus.
0x0
13 RABRT_SLVFLUSH_TX
FIFO
1: Slave has received a read command and some data exists
in the TX FIFO so the slave issues a TX_ABRT interrupt to
flush old data in TX FIFO.
0x0
12 RARB_LOST 1: Master has lost arbitration, or if
I2C_TX_ABRT_SOURCE[14] is also set, then the slave
transmitter has lost arbitration. Note: I2C can be both master
and slave at the same time.
0x0
11 RABRT_MASTER_DIS 1: User tries to initiate a Master operation with the Master
mode disabled.
0x0
10 RABRT_10B_RD_NOR
STRT
1: The restart is disabled (IC_RESTART_EN bit (I2C_CON[5])
= 0) and the master sends a read command in 10-bit address-
ing mode.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 112 Final - January 29, 2015 v3.1
9RABRT_SBYTE_NORS
TRT
To clear Bit 9, the source of the ABRT_SBYTE_NORSTRT
must be fixed first; restart must be enabled (I2C_CON[5]=1),
the SPECIAL bit must be cleared (I2C_TAR[11]), or the
GC_OR_START bit must be cleared (I2C_TAR[10]). Once the
source of the ABRT_SBYTE_NORSTRT is fixed, then this bit
can be cleared in the same manner as other bits in this regis-
ter. If the source of the ABRT_SBYTE_NORSTRT is not fixed
before attempting to clear this bit, bit 9 clears for one cycle
and then gets re-asserted. 1: The restart is disabled
(IC_RESTART_EN bit (I2C_CON[5]) = 0) and the user is try-
ing to send a START Byte.
0x0
8RABRT_HS_NORSTRT 1: The restart is disabled (IC_RESTART_EN bit (I2C_CON[5])
= 0) and the user is trying to use the master to transfer data in
High Speed mode
0x0
7RABRT_SBYTE_ACKD
ET
1: Master has sent a START Byte and the START Byte was
acknowledged (wrong behavior).
0x0
6RABRT_HS_ACKDET 1: Master is in High Speed mode and the High Speed Master
code was acknowledged (wrong behavior).
0x0
5RABRT_GCALL_READ 1: the controller in master mode sent a General Call but the
user programmed the byte following the General Call to be a
read from the bus (IC_DATA_CMD[9] is set to 1).
0x0
4RABRT_GCALL_NOAC
K
1: the controller in master mode sent a General Call and no
slave on the bus acknowledged the General Call.
0x0
3RABRT_TXDATA_NOA
CK
1: This is a master-mode only bit. Master has received an
acknowledgement for the address, but when it sent data
byte(s) following the address, it did not receive an acknowl-
edge from the remote slave(s).
0x0
2RABRT_10ADDR2_NO
ACK
1: Master is in 10-bit address mode and the second address
byte of the 10-bit address was not acknowledged by any
slave.
0x0
1RABRT_10ADDR1_NO
ACK
1: Master is in 10-bit address mode and the first 10-bit
address byte was not acknowledged by any slave.
0x0
0RABRT_7B_ADDR_NO
ACK
1: Master is in 7-bit addressing mode and the address sent
was not acknowledged by any slave.
0x0
Table 179: I2C_TX_ABRT_SOURCE_REG (0x50001380)
Bit Mode Symbol Description Reset
Table 180: I2C_SDA_SETUP_REG (0x50001394)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W SDA_SETUP SDA Setup.
This register controls the amount of time delay (number of I2C
clock periods) between the rising edge of SCL and SDA
changing by holding SCL low when I2C block services a read
request while operating as a slave-transmitter. The relevant
I2C requirement is tSU:DAT (note 4) as detailed in the I2C
Bus Specification. This register must be programmed with a
value equal to or greater than 2.
It is recommended that if the required delay is 1000ns, then
for an I2C frequency of 10 MHz, IC_SDA_SETUP should be
programmed to a value of 11.Writes to this register succeed
only when IC_ENABLE[0] = 0.
0x64
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 113 Final - January 29, 2015 v3.1
Table 181: I2C_ACK_GENERAL_CALL_REG (0x50001398)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0R/W ACK_GEN_CALL ACK General Call. When set to 1, I2C Ctrl responds with a
ACK (by asserting ic_data_oe) when it receives a General
Call. When set to 0, the controller does not generate General
Call interrupts.
0x0
Table 182: I2C_ENABLE_STATUS_REG (0x5000139C)
Bit Mode Symbol Description Reset
15:3 --Reserved 0x0
2RSLV_RX_DATA_LOST Slave Received Data Lost. This bit indicates if a Slave-
Receiver
operation has been aborted with at least one data byte
received from an I2C transfer due to the setting of
IC_ENABLE from 1 to 0. When read as 1, the controller is
deemed to have been actively engaged in an aborted I2C
transfer (with matching address) and the data phase of the
I2C transfer has been entered, even though a data byte has
been responded with a NACK. NOTE: If the remote I2C mas-
ter terminates the transfer with a STOP condition before the
controller has a chance to NACK a transfer, and IC_ENABLE
has been set to 0, then this bit is also set to 1.
When read as 0, the controller is deemed to have been disa-
bled without being actively involved in the data phase of a
Slave-Receiver transfer.
NOTE: The CPU can safely read this bit when IC_EN (bit 0) is
read as 0.
0x0
1RSLV_DISABLED_WHI
LE_BUSY
Slave Disabled While Busy (Transmit, Receive). This bit indi-
cates if a potential or active Slave operation has been aborted
due to the setting of the IC_ENABLE register from 1 to 0. This
bit is set when the CPU writes a 0 to the IC_ENABLE register
while:
(a) I2C Ctrl is receiving the address byte of the Slave-Trans-
mitter operation from a remote master; OR,
(b) address and data bytes of the Slave-Receiver operation
from a remote master. When read as 1, the controller is
deemed to have forced a NACK during any part of an I2C
transfer, irrespective of whether the I2C address matches the
slave address set in I2C Ctrl (IC_SAR register) OR if the
transfer is completed before IC_ENABLE is set to 0 but has
not taken effect.
NOTE: If the remote I2C master terminates the transfer with a
STOP condition before the the controller has a chance to
NACK a transfer, and IC_ENABLE has been set to 0, then
this bit will also be set to 1.
When read as 0, the controller is deemed to have been disa-
bled when there is master activity, or when the I2C bus is idle.
NOTE: The CPU can safely read this bit when IC_EN (bit 0) is
read as 0.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 114 Final - January 29, 2015 v3.1
0RIC_EN ic_en Status. This bit always reflects the value driven on the
output port ic_en. When read as 1, the controller is deemed to
be in an enabled state.
When read as 0, the controller is deemed completely inactive.
NOTE: The CPU can safely read this bit anytime. When this
bit is read as 0, the CPU can safely read
SLV_RX_DATA_LOST (bit 2) and
SLV_DISABLED_WHILE_BUSY (bit 1).
0x0
Table 182: I2C_ENABLE_STATUS_REG (0x5000139C)
Bit Mode Symbol Description Reset
Table 183: I2C_IC_FS_SPKLEN_REG (0x500013A0)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W IC_FS_SPKLEN This register must be set before any I2C bus transaction can
take place to ensure stable operation. This register sets the
duration, measured in ic_clk cycles, of the longest spike in the
SCL or SDA lines that will be filtered out by the spike suppres-
sion logic. This register can be written only when the I2C
interface is disabled which corresponds to the IC_ENABLE
register being set to 0. Writes at other times have no effect.
The minimum valid value is 2; hardware prevents values less
than this being written, and if attempted results in 2 being set.
0x1
Table 184: GPIO_IRQ0_IN_SEL_REG (0x50001400)
Bit Mode Symbol Description Reset
15:6 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 115 Final - January 29, 2015 v3.1
5:0 R/W KBRD_IRQ0_SEL input selection that can generate a GPIO interrupt
0: no input selected
1: P0[0] is selected
2: P0[1] is selected
3: P0[2] is selected
4: P0[3] is selected
5: P0[4] is selected
6: P0[5] is selected
7: P0[6] is selected
8: P0[7] is selected
9: P1[0] is selected
10: P1[1] is selected
11: P1[2] is selected
12: P1[3] is selected
13: P1[4] is selected
14: P1[5] is selected
15: P2[0] is selected
16: P2[1] is selected
17: P2[2] is selected
18: P2[3] is selected
19: P2[4] is selected
20: P2[5] is selected
21: P2[6] is selected
22: P2[7] is selected
23: P2[8] is selected
24: P2[9] is selected
25: P3[0] is selected
26: P3[1] is selected
27: P3[2] is selected
28: P3[3] is selected
29: P3[4] is selected
30: P3[5] is selected
31: P3[6] is selected
32: P3[7] is selected
all others: no input selected
0x0
Table 184: GPIO_IRQ0_IN_SEL_REG (0x50001400)
Bit Mode Symbol Description Reset
Table 185: GPIO_IRQ1_IN_SEL_REG (0x50001402)
Bit Mode Symbol Description Reset
15:5 --Reserved 0x0
5:0 R/W KBRD_IRQ1_SEL see KBRD_IRQ0_SEL 0x0
Table 186: GPIO_IRQ2_IN_SEL_REG (0x50001404)
Bit Mode Symbol Description Reset
15:5 --Reserved 0x0
5:0 R/W KBRD_IRQ2_SEL see KBRD_IRQ0_SEL 0x0
Table 187: GPIO_IRQ3_IN_SEL_REG (0x50001406)
Bit Mode Symbol Description Reset
15:5 --Reserved 0x0
5:0 R/W KBRD_IRQ3_SEL see KBRD_IRQ0_SEL 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 116 Final - January 29, 2015 v3.1
Table 188: GPIO_IRQ4_IN_SEL_REG (0x50001408)
Bit Mode Symbol Description Reset
15:5 --Reserved 0x0
5:0 R/W KBRD_IRQ4_SEL see KBRD_IRQ0_SEL 0x0
Table 189: GPIO_DEBOUNCE_REG (0x5000140C)
Bit Mode Symbol Description Reset
15:14 --Reserved 0x0
13 R/W DEB_ENABLE_KBRD enables the debounce counter for the KBRD interface 0x0
12 R/W DEB_ENABLE4 enables the debounce counter for GPIO IRQ4 0x0
11 R/W DEB_ENABLE3 enables the debounce counter for GPIO IRQ3 0x0
10 R/W DEB_ENABLE2 enables the debounce counter for GPIO IRQ2 0x0
9R/W DEB_ENABLE1 enables the debounce counter for GPIO IRQ1 0x0
8R/W DEB_ENABLE0 enables the debounce counter for GPIO IRQ0 0x0
7:6 --Reserved 0x0
5:0 R/W DEB_VALUE Keyboard debounce time if enabled. Generate KEYB_INT
after specified time.
Debounce time: N*1 ms. N =0..63
0x0
Table 190: GPIO_RESET_IRQ_REG (0x5000140E)
Bit Mode Symbol Description Reset
15:6 --Reserved 0x0
5R0/W RESET_KBRD_IRQ writing a 1 to this bit will reset the KBRD IRQ.
Reading returns 0.
0x0
4R0/W RESET_GPIO4_IRQ writing a 1 to this bit will reset the GPIO4 IRQ.
Reading returns 0.
0x0
3R0/W RESET_GPIO3_IRQ writing a 1 to this bit will reset the GPIO3 IRQ.
Reading returns 0.
0x0
2R0/W RESET_GPIO2_IRQ writing a 1 to this bit will reset the GPIO2 IRQ.
Reading returns 0.
0x0
1R0/W RESET_GPIO1_IRQ writing a 1 to this bit will reset the GPIO1 IRQ.
Reading returns 0.
0x0
0R0/W RESET_GPIO0_IRQ writing a 1 to this bit will reset the GPIO0 IRQ.
Reading returns 0.
0x0
Table 191: GPIO_INT_LEVEL_CTRL_REG (0x50001410)
Bit Mode Symbol Description Reset
15:14 --Reserved 0x0
12 R/W EDGE_LEVELN4 see EDGE_LEVELn0, but for GPIO IRQ4 0x0
11 R/W EDGE_LEVELN3 see EDGE_LEVELn0, but for GPIO IRQ3 0x0
10 R/W EDGE_LEVELN2 see EDGE_LEVELn0, but for GPIO IRQ2 0x0
9R/W EDGE_LEVELN1 see EDGE_LEVELn0, but for GPIO IRQ1 0x0
8R/W EDGE_LEVELN0 0: do not wait for key release after interrupt was reset for
GPIO IRQ0, so a new interrupt can be initiated immediately
1: wait for key release after interrupt was reset for IRQ0
0x0
7:6 --Reserved 0x0
4R/W INPUT_LEVEL4 see INPUT_LEVEL0, but for GPIO IRQ4 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 117 Final - January 29, 2015 v3.1
3R/W INPUT_LEVEL3 see INPUT_LEVEL0, but for GPIO IRQ3 0x0
2R/W INPUT_LEVEL2 see INPUT_LEVEL0, but for GPIO IRQ2 0x0
1R/W INPUT_LEVEL1 see INPUT_LEVEL0, but for GPIO IRQ1 0x0
0R/W INPUT_LEVEL0 0 = selected input will generate GPIO IRQ0 if that input is
high.
1 = selected input will generate GPIO IRQ0 if that input is low.
0x0
Table 191: GPIO_INT_LEVEL_CTRL_REG (0x50001410)
Bit Mode Symbol Description Reset
Table 192: KBRD_IRQ_IN_SEL0_REG (0x50001412)
Bit Mode Symbol Description Reset
15 R/W KBRD_REL 0 = No interrupt on key release
1 = Interrupt also on key release (also debouncing if enabled)
0x0
14 R/W KBRD_LEVEL 0 = enabled input will generate KBRD IRQ if that input is high.
1 = enabled input will generate KBRD IRQ if that input is low.
0x0
13:8 R/W KEY_REPEAT While key is pressed, automatically generate repeating
KEYB_INT after specified time unequal to 0.
Repeat time: N*1 ms. N =1..63, N=0 disables the timer.
0x0
7R/W KBRD_P07_EN enable P0[7] for the keyboard interrupt 0x0
6R/W KBRD_P06_EN enable P0[6] for the keyboard interrupt 0x0
5R/W KBRD_P05_EN enable P0[5] for the keyboard interrupt 0x0
4R/W KBRD_P04_EN enable P0[4] for the keyboard interrupt 0x0
3R/W KBRD_P03_EN enable P0[3] for the keyboard interrupt 0x0
2R/W KBRD_P02_EN enable P0[2] for the keyboard interrupt 0x0
1R/W KBRD_P01_EN enable P0[1] for the keyboard interrupt 0x0
0R/W KBRD_P00_EN enable P0[0] for the keyboard interrupt 0x0
Table 193: KBRD_IRQ_IN_SEL1_REG (0x50001414)
Bit Mode Symbol Description Reset
15 R/W KBRD_P15_EN enable P1[5] for the keyboard interrupt 0x0
14 R/W KBRD_P14_EN enable P1[4] for the keyboard interrupt 0x0
13 R/W KBRD_P13_EN enable P1[3] for the keyboard interrupt 0x0
12 R/W KBRD_P12_EN enable P1[2] for the keyboard interrupt 0x0
11 R/W KBRD_P11_EN enable P1[1] for the keyboard interrupt 0x0
10 R/W KBRD_P10_EN enable P1[0] for the keyboard interrupt 0x0
9R/W KBRD_P29_EN enable P2[9] for the keyboard interrupt 0x0
8R/W KBRD_P28_EN enable P2[8] for the keyboard interrupt 0x0
7R/W KBRD_P27_EN enable P2[7] for the keyboard interrupt 0x0
6R/W KBRD_P26_EN enable P2[6] for the keyboard interrupt 0x0
5R/W KBRD_P25_EN enable P2[5] for the keyboard interrupt 0x0
4R/W KBRD_P24_EN enable P2[4] for the keyboard interrupt 0x0
3R/W KBRD_P23_EN enable P2[3] for the keyboard interrupt 0x0
2R/W KBRD_P22_EN enable P2[2] for the keyboard interrupt 0x0
1R/W KBRD_P21_EN enable P2[1] for the keyboard interrupt 0x0
0R/W KBRD_P20_EN enable P2[0] for the keyboard interrupt 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 118 Final - January 29, 2015 v3.1
Table 194: KBRD_IRQ_IN_SEL2_REG (0x50001416)
Bit Mode Symbol Description Reset
7R/W KBRD_P37_EN enable P3[7] for the keyboard interrupt 0x0
6R/W KBRD_P36_EN enable P3[6] for the keyboard interrupt 0x0
5R/W KBRD_P35_EN enable P3[5] for the keyboard interrupt 0x0
4R/W KBRD_P34_EN enable P3[4] for the keyboard interrupt 0x0
3R/W KBRD_P33_EN enable P3[3] for the keyboard interrupt 0x0
2R/W KBRD_P32_EN enable P3[2] for the keyboard interrupt 0x0
1R/W KBRD_P31_EN enable P3[1] for the keyboard interrupt 0x0
0R/W KBRD_P30_EN enable P3[0] for the keyboard interrupt 0x0
Table 195: GP_ADC_CTRL_REG (0x50001500)
Bit Mode Symbol Description Reset
15 R/W GP_ADC_LDO_ZERO Forces LDO-output to 0V. 0x0
14 R/W GP_ADC_LDO_EN Turns on LDO. 0x0
13 R/W GP_ADC_CHOP Takes two samples with opposite GP_ADC_SIGN to cancel
the internal offset voltage of the ADC; Highly recommended
for DC-measurements.
0x0
12 R/W GP_ADC_MUTE Takes sample at mid-scale (to dertermine the internal offset
and/or noise of the ADC with regards to VDD_REF which is
also sampled by the ADC).
0x0
11 R/W GP_ADC_SE 0 = Differential mode
1 = Single ended mode
0x0
10 R/W GP_ADC_SIGN 0 = Default
1 = Conversion with opposite sign at input and output to can-
cel out the internal offset of the ADC and low-frequency
0x0
9:6 R/W GP_ADC_SEL ADC input selection which must be set before the
GP_ADC_START bit is enabled.
If GP_ADC_SE = 1 (single ended mode):
0000 = P0[0]
0001 = P0[1]
0010 = P0[2]
0011 = P0[3]
0100 = AVS
0101 = VDD_REF
0110 = VDD_RTT
0111 = VBAT3V
1000 = VDCDC
1001 = VBAT1V
All other combinations are reserved.
If GP_ADC_SE = 0 (differential mode):
0000 = P0[0] vs P0[1]
All other combinations are P0[2] vs P0[3].
0x0
5R/W GP_ADC_MINT 0 = Disable (mask) GP_ADC_INT.
1 = Enable GP_ADC_INT to ICU.
0x0
4RGP_ADC_INT 1 = AD conversion ready and has generated an interrupt.
Must be cleared by writing any value to
GP_ADC_CLEAR_INT_REG.
0x0
3R/W GP_ADC_CLK_SEL 0 = Internal high-speed ADC clock used.
1 = Digital clock used.
0x0
2-GP_ADC_TEST Reserved, keep 0. 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 119 Final - January 29, 2015 v3.1
1R/W GP_ADC_START 0 = ADC conversion ready.
1 = If a 1 is written, the ADC starts a conversion. After the
conversion this bit will be set to 0 and the GP_ADC_INT bit
will be set.
0x0
0R/W GP_ADC_EN 0 = ADC is disabled and in reset.
1 = ADC is enabled and sampling of input is started.
0x0
Table 195: GP_ADC_CTRL_REG (0x50001500)
Bit Mode Symbol Description Reset
Table 196: GP_ADC_CTRL2_REG (0x50001502)
Bit Mode Symbol Description Reset
15:4 --Reserved 0x0
3R/W GP_ADC_I20U Adds 20uA constant load current at the ADC LDO to minimize
ripple on the reference voltage of the ADC.
0x0
2R/W GP_ADC_IDYN Enables dynamic load current at the ADC LDO to minimize
ripple on the reference voltage of the ADC.
0x0
1R/W GP_ADC_ATTN3X 0 = Input voltages up to 1.2V allowed.
1 = Input voltages up to 3.6V allowed by enabling 3x attenua-
tor.
0x0
0R/W GP_ADC_DELAY_EN Enables delay function for several signals. This is not auto-
cleared. Toggle this bit before every sampling to enable suc-
cesive conversions.
0x0
Table 197: GP_ADC_OFFP_REG (0x50001504)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:0 R/W GP_ADC_OFFP Offset adjust of 'positive' array of ADC-network (effective if
"GP_ADC_SE=0", or "GP_ADC_SE=1 AND
GP_ADC_SIGN=0")
0x200
Table 198: GP_ADC_OFFN_REG (0x50001506)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:0 R/W GP_ADC_OFFN Offset adjust of 'negative' array of ADC-network (effective if
"GP_ADC_SE=0", or "GP_ADC_SE=1 AND
GP_ADC_SIGN=1")
0x200
Table 199: GP_ADC_CLEAR_INT_REG (0x50001508)
Bit Mode Symbol Description Reset
15:0 R0/W GP_ADC_CLR_INT Writing any value to this register will clear the ADC_INT inter-
rupt. Reading returns 0.
0x0
Table 200: GP_ADC_RESULT_REG (0x5000150A)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:0 RGP_ADC_VAL Returns the 10 bits linear value of the last AD conversion. 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 120 Final - January 29, 2015 v3.1
Table 201: GP_ADC_DELAY_REG (0x5000150C)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W DEL_LDO_EN Defines the delay before the LDO enable
(GP_ADC_LDO_EN). Reset value is 0 µs since the LDO ena-
ble should be the first thing to be programmed in the
sequence of bringing the GP ADC up.
0x0
Table 202: GP_ADC_DELAY2_REG (0x5000150E)
Bit Mode Symbol Description Reset
15:8 R/W DEL_ADC_START Defines the delay for the GP_ADC_START bit. Reset value is
17 µs which is the recommended value to wait before starting
the GP ADC. This is the third and last step of bringing up the
GP ADC
0x88
7:0 R/W DEL_ADC_EN Defines the delay for the GP_ADC_EN bit. Reset value is 16
µs which is the recommended value to wait after enabling the
LDO. This is the second step in bringing up the GP ADC.
0x80
Table 203: CLK_REF_SEL_REG (0x50001600)
Bit Mode Symbol Description Reset
15:3 --Reserved 0x0
2R/W REF_CAL_START Writing a '1' starts a calibration. This bit is cleared when cali-
bration is finished, and CLK_REF_VAL is ready.
0x0
1:0 R/W REF_CLK_SEL Select clock input for calibration:
0x0 : RC32KHz oscillator
0x1 : RC16MHz oscillator
0x2 : XTAL32KHz oscillator
0x3 : RCX32KHz oscillator
0x0
Table 204: CLK_REF_CNT_REG (0x50001602)
Bit Mode Symbol Description Reset
15:0 R/W REF_CNT_VAL Indicates the calibration time, with a decrement counter to 1. 0x0
Table 205: CLK_REF_VAL_L_REG (0x50001604)
Bit Mode Symbol Description Reset
15:0 RXTAL_CNT_VAL Returns the lower 16 bits of XTAL16 clock cycles during the
calibration time, defined with REF_CNT_VAL
0x0
Table 206: CLK_REF_VAL_H_REG (0x50001606)
Bit Mode Symbol Description Reset
15:0 RXTAL_CNT_VAL Returns the upper 16 bits of XTAL16 clock cycles during the
calibration time, defined with REF_CNT_VAL
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 121 Final - January 29, 2015 v3.1
Table 207: P0_DATA_REG (0x50003000)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W P0_DATA Set P0 output register when written; Returns the value of P0
port when read
0x0
Table 208: P0_SET_DATA_REG (0x50003002)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W P0_SET Writing a 1 to P0[y] sets P0[y] to 1. Writing 0 is discarded;
Reading returns 0
0x0
Table 209: P0_RESET_DATA_REG (0x50003004)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W P0_RESET Writing a 1 to P0[y] sets P0[y] to 0. Writing 0 is discarded;
Reading returns 0
0x0
Table 210: P00_MODE_REG (0x50003006)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
0x2
7:5 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 122 Final - January 29, 2015 v3.1
4:0 R/W PID Function of port
0 = Port function, PUPD as set above
1 = UART1_RX
2 = UART1_TX
3 = UART2_RX
4 = UART2_TX
5 = SPI_DI
6 = SPI_DO
7 = SPI_CLK
8 = SPI_EN
9 = I2C_SCL
10 = I2C_SDA
11 = UART1_IRDA_RX
12 = UART1_IRDA_TX
13 = UART2_IRDA_RX
14 = UART2_IRDA_TX
15 = ADC (only for P0[3:0])
16 = PWM0
17 = PWM1
18 = BLE_DIAG (only for P0[7:0])
19 = UART1_CTSN
20 = UART1_RTSN
21 = UART2_CTSN
22 = UART2_RTSN
23 = PWM2
24 = PWM3
25 = PWM4
Note: when a certain input function (like SPI_DI) is selected
on more than 1 port pin, the port with the lowest index has the
highest priority and P0 has higher priority than P1.
0x0
Table 210: P00_MODE_REG (0x50003006)
Bit Mode Symbol Description Reset
Table 211: P01_MODE_REG (0x50003008)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
0x2
7:5 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 123 Final - January 29, 2015 v3.1
4:0 R/W PID Function of port
0 = Port function, PUPD as set above
1 = UART1_RX
2 = UART1_TX
3 = UART2_RX
4 = UART2_TX
5 = SPI_DI
6 = SPI_DO
7 = SPI_CLK
8 = SPI_EN
9 = I2C_SCL
10 = I2C_SDA
11 = UART1_IRDA_RX
12 = UART1_IRDA_TX
13 = UART2_IRDA_RX
14 = UART2_IRDA_TX
15 = ADC (only for P0[3:0])
16 = PWM0
17 = PWM1
18 = BLE_DIAG (only for P0[7:0])
19 = UART1_CTSN
20 = UART1_RTSN
21 = UART2_CTSN
22 = UART2_RTSN
23 = PWM2
24 = PWM3
25 = PWM4
Note: when a certain input function (like SPI_DI) is selected
on more than 1 port pin, the port with the lowest index has the
highest priority and P0 has higher priority than P1.
0x0
Table 211: P01_MODE_REG (0x50003008)
Bit Mode Symbol Description Reset
Table 212: P02_MODE_REG (0x5000300A)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
0x2
7:5 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 124 Final - January 29, 2015 v3.1
4:0 R/W PID Function of port
0 = Port function, PUPD as set above
1 = UART1_RX
2 = UART1_TX
3 = UART2_RX
4 = UART2_TX
5 = SPI_DI
6 = SPI_DO
7 = SPI_CLK
8 = SPI_EN
9 = I2C_SCL
10 = I2C_SDA
11 = UART1_IRDA_RX
12 = UART1_IRDA_TX
13 = UART2_IRDA_RX
14 = UART2_IRDA_TX
15 = ADC (only for P0[3:0])
16 = PWM0
17 = PWM1
18 = BLE_DIAG (only for P0[7:0])
19 = UART1_CTSN
20 = UART1_RTSN
21 = UART2_CTSN
22 = UART2_RTSN
23 = PWM2
24 = PWM3
25 = PWM4
Note: when a certain input function (like SPI_DI) is selected
on more than 1 port pin, the port with the lowest index has the
highest priority and P0 has higher priority than P1.
0x0
Table 212: P02_MODE_REG (0x5000300A)
Bit Mode Symbol Description Reset
Table 213: P03_MODE_REG (0x5000300C)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
0x2
7:5 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 125 Final - January 29, 2015 v3.1
4:0 R/W PID Function of port
0 = Port function, PUPD as set above
1 = UART1_RX
2 = UART1_TX
3 = UART2_RX
4 = UART2_TX
5 = SPI_DI
6 = SPI_DO
7 = SPI_CLK
8 = SPI_EN
9 = I2C_SCL
10 = I2C_SDA
11 = UART1_IRDA_RX
12 = UART1_IRDA_TX
13 = UART2_IRDA_RX
14 = UART2_IRDA_TX
15 = ADC (only for P0[3:0])
16 = PWM0
17 = PWM1
18 = BLE_DIAG (only for P0[7:0])
19 = UART1_CTSN
20 = UART1_RTSN
21 = UART2_CTSN
22 = UART2_RTSN
23 = PWM2
24 = PWM3
25 = PWM4
Note: when a certain input function (like SPI_DI) is selected
on more than 1 port pin, the port with the lowest index has the
highest priority and P0 has higher priority than P1.
0x0
Table 213: P03_MODE_REG (0x5000300C)
Bit Mode Symbol Description Reset
Table 214: P04_MODE_REG (0x5000300E)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
0x2
7:5 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 126 Final - January 29, 2015 v3.1
4:0 R/W PID Function of port
0 = Port function, PUPD as set above
1 = UART1_RX
2 = UART1_TX
3 = UART2_RX
4 = UART2_TX
5 = SPI_DI
6 = SPI_DO
7 = SPI_CLK
8 = SPI_EN
9 = I2C_SCL
10 = I2C_SDA
11 = UART1_IRDA_RX
12 = UART1_IRDA_TX
13 = UART2_IRDA_RX
14 = UART2_IRDA_TX
15 = ADC (only for P0[3:0])
16 = PWM0
17 = PWM1
18 = BLE_DIAG (only for P0[7:0])
19 = UART1_CTSN
20 = UART1_RTSN
21 = UART2_CTSN
22 = UART2_RTSN
23 = PWM2
24 = PWM3
25 = PWM4
Note: when a certain input function (like SPI_DI) is selected
on more than 1 port pin, the port with the lowest index has the
highest priority and P0 has higher priority than P1.
0x0
Table 214: P04_MODE_REG (0x5000300E)
Bit Mode Symbol Description Reset
Table 215: P05_MODE_REG (0x50003010)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
0x2
7:5 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 127 Final - January 29, 2015 v3.1
4:0 R/W PID Function of port
0 = Port function, PUPD as set above
1 = UART1_RX
2 = UART1_TX
3 = UART2_RX
4 = UART2_TX
5 = SPI_DI
6 = SPI_DO
7 = SPI_CLK
8 = SPI_EN
9 = I2C_SCL
10 = I2C_SDA
11 = UART1_IRDA_RX
12 = UART1_IRDA_TX
13 = UART2_IRDA_RX
14 = UART2_IRDA_TX
15 = ADC (only for P0[3:0])
16 = PWM0
17 = PWM1
18 = BLE_DIAG (only for P0[7:0])
19 = UART1_CTSN
20 = UART1_RTSN
21 = UART2_CTSN
22 = UART2_RTSN
23 = PWM2
24 = PWM3
25 = PWM4
Note: when a certain input function (like SPI_DI) is selected
on more than 1 port pin, the port with the lowest index has the
highest priority and P0 has higher priority than P1.
0x0
Table 215: P05_MODE_REG (0x50003010)
Bit Mode Symbol Description Reset
Table 216: P06_MODE_REG (0x50003012)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
0x2
7:5 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 128 Final - January 29, 2015 v3.1
4:0 R/W PID Function of port
0 = Port function, PUPD as set above
1 = UART1_RX
2 = UART1_TX
3 = UART2_RX
4 = UART2_TX
5 = SPI_DI
6 = SPI_DO
7 = SPI_CLK
8 = SPI_EN
9 = I2C_SCL
10 = I2C_SDA
11 = UART1_IRDA_RX
12 = UART1_IRDA_TX
13 = UART2_IRDA_RX
14 = UART2_IRDA_TX
15 = ADC (only for P0[3:0])
16 = PWM0
17 = PWM1
18 = BLE_DIAG (only for P0[7:0])
19 = UART1_CTSN
20 = UART1_RTSN
21 = UART2_CTSN
22 = UART2_RTSN
23 = PWM2
24 = PWM3
25 = PWM4
Note: when a certain input function (like SPI_DI) is selected
on more than 1 port pin, the port with the lowest index has the
highest priority and P0 has higher priority than P1.
0x0
Table 216: P06_MODE_REG (0x50003012)
Bit Mode Symbol Description Reset
Table 217: P07_MODE_REG (0x50003014)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
0x2
7:5 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 129 Final - January 29, 2015 v3.1
4:0 R/W PID Function of port
0 = Port function, PUPD as set above
1 = UART1_RX
2 = UART1_TX
3 = UART2_RX
4 = UART2_TX
5 = SPI_DI
6 = SPI_DO
7 = SPI_CLK
8 = SPI_EN
9 = I2C_SCL
10 = I2C_SDA
11 = UART1_IRDA_RX
12 = UART1_IRDA_TX
13 = UART2_IRDA_RX
14 = UART2_IRDA_TX
15 = ADC (only for P0[3:0])
16 = PWM0
17 = PWM1
18 = BLE_DIAG (only for P0[7:0])
19 = UART1_CTSN
20 = UART1_RTSN
21 = UART2_CTSN
22 = UART2_RTSN
23 = PWM2
24 = PWM3
25 = PWM4
Note: when a certain input function (like SPI_DI) is selected
on more than 1 port pin, the port with the lowest index has the
highest priority and P0 has higher priority than P1.
0x0
Table 217: P07_MODE_REG (0x50003014)
Bit Mode Symbol Description Reset
Table 218: P1_DATA_REG (0x50003020)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W P1_DATA Set P1 output register when written; Returns the value of P1
port when read
0x0
Table 219: P1_SET_DATA_REG (0x50003022)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W P1_SET Writing a 1 to P1[y] sets P1[y] to 1. Writing 0 is discarded;
Reading returns 0
0x0
Table 220: P1_RESET_DATA_REG (0x50003024)
Bit Mode Symbol Description Reset
15:8 --Reserved 0x0
7:0 R/W P1_RESET Writing a 1 to P1[y] sets P1[y] to 0. Writing 0 is discarded;
Reading returns 0
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 130 Final - January 29, 2015 v3.1
Table 221: P10_MODE_REG (0x50003026)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
P14_MODE_REG and P15_MODE_REG reset value is 1 (i.e.
pulled up)
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 222: P11_MODE_REG (0x50003028)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
P14_MODE_REG and P15_MODE_REG reset value is 1 (i.e.
pulled up)
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 223: P12_MODE_REG (0x5000302A)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
P14_MODE_REG and P15_MODE_REG reset value is 1 (i.e.
pulled up)
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 224: P13_MODE_REG (0x5000302C)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
P14_MODE_REG and P15_MODE_REG reset value is 1 (i.e.
pulled up)
0x2
7:5 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 131 Final - January 29, 2015 v3.1
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 224: P13_MODE_REG (0x5000302C)
Bit Mode Symbol Description Reset
Table 225: P14_MODE_REG (0x5000302E)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
P14_MODE_REG and P15_MODE_REG reset value is 1 (i.e.
pulled up)
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 226: P15_MODE_REG (0x50003030)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
P14_MODE_REG and P15_MODE_REG reset value is 1 (i.e.
pulled up)
0x1
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 227: P2_DATA_REG (0x50003040)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:0 R/W P2_DATA Set P2 output register when written; Returns the value of P2
port when read
0x0
Table 228: P2_SET_DATA_REG (0x50003042)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:0 R/W P2_SET Writing a 1 to P2[y] sets P2[y] to 1. Writing 0 is discarded;
Reading returns 0
0x0
Table 229: P2_RESET_DATA_REG (0x50003044)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:0 R/W P2_RESET Writing a 1 to P2[y] sets P2[y] to 0. Writing 0 is discarded;
Reading returns 0
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 132 Final - January 29, 2015 v3.1
Table 230: P20_MODE_REG (0x50003046)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 231: P21_MODE_REG (0x50003048)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 232: P22_MODE_REG (0x5000304A)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 233: P23_MODE_REG (0x5000304C)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 234: P24_MODE_REG (0x5000304E)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 133 Final - January 29, 2015 v3.1
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 234: P24_MODE_REG (0x5000304E)
Bit Mode Symbol Description Reset
Table 235: P25_MODE_REG (0x50003050)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 236: P26_MODE_REG (0x50003052)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 237: P27_MODE_REG (0x50003054)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 238: P28_MODE_REG (0x50003056)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 134 Final - January 29, 2015 v3.1
Note 3: For buck mode the output must be powered by the 3V rail, for boost mode by the 1V rail.
Note 4: For buck mode the output must be powered by the 3V rail, for boost mode by the 1V rail.
Note 5: For buck mode the output must be powered by the 3V rail, for boost mode by the 1V rail.
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 238: P28_MODE_REG (0x50003056)
Bit Mode Symbol Description Reset
Table 239: P29_MODE_REG (0x50003058)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In analog mode, these bits are don't care
0x2
7:5 --Reserved 0x0
4:0 R/W PID See P0x_MODE_REG[PID] 0x0
Table 240: P01_PADPWR_CTRL_REG (0x50003070)
Bit Mode Symbol Description Reset
15:12 --Reserved 0x0
13:8 R/W P1_OUT_CTRL 1 = P1_x port output is powered by 1V rail
0 = P1_x port output is powered by 3V rail
bit 8 controls the power of P1[0],
bit 13 controls the power of P1[5]
(Note 3)
0x0
7:0 R/W P0_OUT_CTRL 1 = P0_x port output is powered by 1V rail
0 = P0_x port output is powered by 3V rail
bit 0 controls the power of P0[0],
bit 7 controls the power of P0[7]
(Note 4)
0x0
Table 241: P2_PADPWR_CTRL_REG (0x50003072)
Bit Mode Symbol Description Reset
15:10 --Reserved 0x0
9:0 R/W P2_OUT_CTRL 1 = P2_x port output is powered by 1V rail
0 = P2_x port output is powered by 3V rail
bit 0 controls the power of P2[0],
bit 9 controls the power of P2[9],
(Note 5)
0x0
Table 242: P3_PADPWR_CTRL_REG (0x50003074)
Bit Mode Symbol Description Reset
15:8 --Reserved 0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 135 Final - January 29, 2015 v3.1
Note 6: For buck mode the output must be powered by the 3V rail, for boost mode by the 1V rail.
7:0 R/W P3_OUT_CTRL 1 = P3_x port output is powered by 1V rail
0 = P3_x port output is powered by 3V rail
bit 0 controls the power of P3[0],
bit 7 controls the power of P3[7],
(Note 6)
0
Table 242: P3_PADPWR_CTRL_REG (0x50003074)
Bit Mode Symbol Description Reset
Table 243: P3_DATA_REG (0x50003080)
Bit Mode Symbol Description Reset
15:8 --Reserved 0
7:0 R/W P3_DATA Set P3 output register when written; Returns the value of P3
port when read
0
Table 244: P3_SET_DATA_REG (0x50003082)
Bit Mode Symbol Description Reset
15:8 --Reserved 0
7:0 R0/W P3_SET Writing a 1 to P3[y] sets P3[y] to 1. Writing 0 is discarded;
Reading returns 0
0
Table 245: P3_RESET_DATA_REG (0x50003084)
Bit Mode Symbol Description Reset
15:8 --Reserved 0
7:0 R0/W P3_RESET Writing a 1 to P0[y] sets P0[y] to 0. Writing 0 is discarded;
Reading returns 0
0
Table 246: P30_MODE_REG (0x50003086)
Bit Mode Symbol Description Reset
15:10 --Reserved 0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
2
7:5 --Reserved 0
4:0 R/W PID See P0x_MODE_REG[PID] 0
Table 247: P31_MODE_REG (0x50003088)
Bit Mode Symbol Description Reset
15:10 --Reserved 0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
2
7:5 --Reserved 0
4:0 R/W PID See P0x_MODE_REG[PID] 0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 136 Final - January 29, 2015 v3.1
Table 248: P32_MODE_REG (0x5000308A)
Bit Mode Symbol Description Reset
15:10 --Reserved 0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
2
7:5 --Reserved 0
4:0 R/W PID See P0x_MODE_REG[PID] 0
Table 249: P33_MODE_REG (0x5000308C)
Bit Mode Symbol Description Reset
15:10 --Reserved 0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
2
7:5 --Reserved 0
4:0 R/W PID See P0x_MODE_REG[PID] 0
Table 250: P34_MODE_REG (0x5000308E)
Bit Mode Symbol Description Reset
15:10 --Reserved 0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
2
7:5 --Reserved 0
4:0 R/W PID See P0x_MODE_REG[PID] 0
Table 251: P35_MODE_REG (0x50003090)
Bit Mode Symbol Description Reset
15:10 --Reserved 0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
2
7:5 --Reserved 0
4:0 R/W PID See P0x_MODE_REG[PID] 0
Table 252: P36_MODE_REG (0x50003092)
Bit Mode Symbol Description Reset
15:10 --Reserved 0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 137 Final - January 29, 2015 v3.1
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
2
7:5 --Reserved 0
4:0 R/W PID See P0x_MODE_REG[PID] 0
Table 252: P36_MODE_REG (0x50003092)
Bit Mode Symbol Description Reset
Table 253: P37_MODE_REG (0x50003094)
Bit Mode Symbol Description Reset
15:10 --Reserved 0
9:8 R/W PUPD 00 = Input, no resistors selected
01 = Input, pull-up selected
10 = Input, Pull-down selected
11 = Output, no resistors selected
In ADC mode, these bits are don't care
2
7:5 --Reserved 0
4:0 R/W PID See P0x_MODE_REG[PID] 0
Table 254: WATCHDOG_REG (0x50003100)
Bit Mode Symbol Description Reset
15:9 R0/W WDOG_WEN 0000.000 = Write enable for Watchdog timer
else Write disable. This filter prevents unintentional presetting
the watchdog with a SW run-away.
0x0
8R/W WDOG_VAL_NEG 0 = Watchdog timer value is positive.
1 = Watchdog timer value is negative.
0x0
7:0 R/W WDOG_VAL Write: Watchdog timer reload value. Note that all bits 15-9
must be 0 to reload this register.
Read: Actual Watchdog timer value. Decremented by 1 every
10.24 msec. Bit 8 indicates a negative counter value. 2, 1, 0,
1FF16, 1FE16 etc. An NMI or WDOG (SYS) reset is generated
under the following conditions:
If WATCHDOG_CTRL_REG[NMI_RST] = 0 then
If WDOG_VAL = 0 -> NMI (Non Maskable Interrupt)
if WDOG_VAL = 1F016 -> WDOG reset -> reload FF16
If WATCHDOG_CTRL_REG[NMI_RST] = 1 then
if WDOG_VAL <= 0 -> WDOG reset -> reload FF16
0xFF
Table 255: WATCHDOG_CTRL_REG (0x50003102)
Bit Mode Symbol Description Reset
15:14 --Reserved 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 138 Final - January 29, 2015 v3.1
0R/W NMI_RST 0 = Watchdog timer generates NMI at value 0, and WDOG
(SYS) reset at <=-16. Timer can be frozen /resumed using
SET_FREEZE_REG[FRZ_WDOG]/
RESET_FREEZE_REG[FRZ_WDOG].
1 = Watchdog timer generates a WDOG (SYS) reset at value
0 and can not be frozen by Software.
Note that this bit can only be set to 1 by SW and only be reset
with a WDOG (SYS) reset or SW reset.
The watchdog is always frozen when the Cortex-M0 is halted
in DEBUG State.
0x0
Table 255: WATCHDOG_CTRL_REG (0x50003102)
Bit Mode Symbol Description Reset
Table 256: CHIP_ID1_REG (0x50003200)
Bit Mode Symbol Description Reset
7:0 RCHIP_ID1 First character of device type "580" in ASCII. 0x35
Table 257: CHIP_ID2_REG (0x50003201)
Bit Mode Symbol Description Reset
7:0 RCHIP_ID2 Second character of device type "580" in ASCII. 0x38
Table 258: CHIP_ID3_REG (0x50003202)
Bit Mode Symbol Description Reset
7:0 RCHIP_ID3 Third character of device type "580" in ASCII. 0x30
Table 259: CHIP_SWC_REG (0x50003203)
Bit Mode Symbol Description Reset
7:4 --Reserved 0x0
3:0 RCHIP_SWC SoftWare Compatibility code.
Integer (default = 0) which is incremented if a silicon change
has impact on the CPU Firmware.
Can be used by software developers to write silicon revision
dependent code.
0x0
Table 260: CHIP_REVISION_REG (0x50003204)
Bit Mode Symbol Description Reset
7:0 RREVISION_ID Chip version, corresponds with type number in ASCII.
0x41 = 'A', 0x42 = 'B'
0x41
Table 261: CHIP_CONFIG1_REG (0x50003205)
Bit Mode Symbol Description Reset
7:0 RCHIP_CONFIG1 First character of Chip Configuration "0M2" in ASCII. 0x30
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 139 Final - January 29, 2015 v3.1
Table 262: CHIP_CONFIG2_REG (0x50003206)
Bit Mode Symbol Description Reset
7:0 RCHIP_CONFIG2 Second character of Chip Configuration "0M2" in ASCII. 0x4D
Table 263: CHIP_CONFIG3_REG (0x50003207)
Bit Mode Symbol Description Reset
7:0 RCHIP_CONFIG3 Third character of Chip Configuration "0M2" in ASCII. 0x32
Table 264: CHIP_TEST1_REG (0x5000320A)
Bit Mode Symbol Description Reset
7:0 --Reserved 0x0
Table 265: CHIP_TEST2_REG (0x5000320B)
Bit Mode Symbol Description Reset
7:0 --Reserved 0x20
Table 266: SET_FREEZE_REG (0x50003300)
Bit Mode Symbol Description Reset
15:4 --Reserved 0x0
3R/W FRZ_WDOG If '1', the watchdog timer is frozen, '0' is discarded.
WATCHDOG_CTRL_REG[NMI_RST] must be '0' to allow the
freeze function.
0x0
2R/W FRZ_BLETIM If '1', the BLE master clock is frozen, '0' is discarded. 0x0
1R/W FRZ_SWTIM If '1', the SW Timer (TIMER0) is frozen, '0' is discarded. 0x0
0R/W FRZ_WKUPTIM If '1', the Wake Up Timer is frozen, '0' is discarded. 0x0
Table 267: RESET_FREEZE_REG (0x50003302)
Bit Mode Symbol Description Reset
15:4 --Reserved 0x0
3R/W FRZ_WDOG If '1', the watchdog timer continues, '0' is discarded. 0x0
2R/W FRZ_BLETIM If '1', the the BLE master clock continues, '0' is discarded. 0x0
1R/W FRZ_SWTIM If '1', the SW Timer (TIMER0) continues, '0' is discarded. 0x0
0R/W FRZ_WKUPTIM If '1', the Wake Up Timer continues, '0' is discarded. 0x0
Table 268: DEBUG_REG (0x50003304)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0R/W DEBUGS_FREEZE_E
N
Default '1', freezing of the on-chip timers is enabled when the
Cortex-M0 is halted in DEBUG State.
If '0', freezing of the on-chip timers is depending on
FREEZE_REG when the Cortex-M0 is halted in DEBUG State
except the watchdog timer. The watchdog timer is always fro-
zen when the Cortex-M0 is halted in DEBUG State.
0x1
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 140 Final - January 29, 2015 v3.1
Table 269: GP_STATUS_REG (0x50003306)
Bit Mode Symbol Description Reset
15:1 --Reserved 0x0
0R/W CAL_PHASE If '1', it designates that the chip is in Calibration Phase i.e. the
OTP has been initially programmed but no Calibration has
occured.
0x0
Table 270: GP_CONTROL_REG (0x50003308)
Bit Mode Symbol Description Reset
15:6 --Reserved 0
5:1 R/W EM_MAP Select the mapping of the Exchange memory pages.
0: EM size 0 kB, SysRAM size 42 kB
1: EM size 2 kB, SysRAM size 48 kB
2: EM size 3 kB, SysRAM size 47 kB
3: EM size 4 kB, SysRAM size 46 kB
4: EM size 5 kB, SysRAM size 45 kB
5: EM size 6 kB, SysRAM size 44 kB
6: EM size 7 kB, SysRAM size 43 kB
7: EM size 8 kB, SysRAM size 42 kB
8: Reserved
9: EM size 4 kB, SysRAM size 40 kB
10: EM size 5 kB, SysRAM size 40 kB
11: EM size 6 kB, SysRAM size 40 kB
12: EM size 7 kB, SysRAM size 40 kB
13: EM size 8 kB, SysRAM size 40 kB
14: EM size 9 kB, SysRAM size 40 kB
15: EM size 10 kB, SysRAM size 40 kB
16: Reserved
17: EM size 6 kB, SysRAM size 38 kB
18: EM size 7 kB, SysRAM size 38 kB
19: EM size 8 kB, SysRAM size 38 kB
20: EM size 9 kB, SysRAM size 38 kB
21: EM size 10 kB, SysRAM size 38 kB
22: EM size 11 kB, SysRAM size 38 kB
23: EM size 12 kB, SysRAM size 38 kB
other: Reserved.
0x1
0R/W BLE_WAKEUP_REQ If '1', the BLE wakes up. 0x0
Table 271: TIMER0_CTRL_REG (0x50003400)
Bit Mode Symbol Description Reset
15:4 --Reserved 0x0
3R/W PWM_MODE 0 = PWM signals are '1' during high time.
1 = PWM signals send out the (fast) clock divided by 2 during
high time. So it will be in the range of 1 to 8 MHz.
0x0
2R/W TIM0_CLK_DIV 1 = Timer0 uses selected clock frequency as is.
0 = Timer0 uses selected clock frequency divided by 10.
Note that this applies only to the ON-counter.
0x0
1R/W TIM0_CLK_SEL 1 = Timer0 uses 16, 8, 4 or 2 MHz (fast) clock frequency.
0 = Timer0 uses 32 kHz (slow) clock frequency.
0x0
0R/W TIM0_CTRL 0 = Timer0 is off and in reset state.
1 = Timer0 is running.
0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 141 Final - January 29, 2015 v3.1
Table 272: TIMER0_ON_REG (0x50003402)
Bit Mode Symbol Description Reset
15:0 R0/W TIM0_ON Timer0 On reload value:
If read the actual counter value ON_CNTer is returned
0x0
Table 273: TIMER0_RELOAD_M_REG (0x50003404)
Bit Mode Symbol Description Reset
15:0 R0/W TIM0_M Timer0 'high' reload valueIf read the actual counter value
T0_CNTer is returned
0x0
Table 274: TIMER0_RELOAD_N_REG (0x50003406)
Bit Mode Symbol Description Reset
15:0 R0/W TIM0_N Timer0 'low' reload value:
If read the actual counter value T0_CNTer is returned
0x0
Table 275: PWM2_DUTY_CYCLE (0x50003408)
Bit Mode Symbol Description Reset
13:0 R/W DUTY_CYCLE duty cycle for PWM 0x0
Table 276: PWM3_DUTY_CYCLE (0x5000340A)
Bit Mode Symbol Description Reset
13:0 R/W DUTY_CYCLE duty cycle for PWM 0x0
Table 277: PWM4_DUTY_CYCLE (0x5000340C)
Bit Mode Symbol Description Reset
13:0 R/W DUTY_CYCLE duty cycle for PWM 0x0
Table 278: TRIPLE_PWM_FREQUENCY (0x5000340E)
Bit Mode Symbol Description Reset
13:0 R/W FREQ Freq for PWM 2 3 4 0x0
Table 279: TRIPLE_PWM_CTRL_REG (0x50003410)
Bit Mode Symbol Description Reset
2R/W HW_PAUSE_EN '1' = HW can pause PWM 2,3,4 0x1
1R/W SW_PAUSE_EN '1' = PWM 2 3 4 is paused 0x0
0R/W TRIPLE_PWM_ENAB
LE
'1' = PWM 2 3 4 is enabled 0x0
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 142 Final - January 29, 2015 v3.1
5. Specifications
All MIN/MAX specification limits are guaranteed by design, production testing and/or statistical characterisation.
Typical values are based on characterisation results at default measurement conditions and are informative only.
Default measurement conditions (unless otherwise specified): VBAT(VBAT3V) = 3.0 V (buck mode), VBAT(VBAT1V)
= 1.2 V (boost mode), TA = 25 C. All radio measurements are performed with standard RF measurement equipment
providing a source/load impedance of 50 .
The specifications in the following tables are valid for the reference circuits shown in Figure 11 (Boost mode) and
Figure 12 (Buck mode).
Figure 11 Alkaline battery cell powered system diagram (Boost mode)
9%$79
9%$7
9GFGF
9GFGF 9%$7
9%$7
<
N
8
'$
933 $
6:B&/. &
3B
%
6:',2 '
;7$/.P )
*1'
)
3B
%
3B
&
3B
(
3B
%
;7$/.S )
5),2S $
*1'
&
3B
&
*1'
'
5),2P $
567
(
3B
'
9%$79 )
*1'
'
3B
'
3B
(
3B
(
9%$79 (
6:,7&+ )
3B
'
3B
&
;7$/0P $
;7$/0S %
9'&'& )
9'&'&B5) $
9%$7B5) (
*1'
$
*1'
%
&
X)
&
$17
%7
9$$$
<
0+]
&
X)
73933
/
X+
736:&/.
&
X)
736:',2
&
739%$7
73*1'
X)
X)
+]
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 143 Final - January 29, 2015 v3.1
Figure 12 Lithium coin cell powered system diagram (Buck mode)
237,21$/
9%$7
9%$7 9GFGF
9GFGF
9%$7
&
736:&/.
<
N
736:',2
X)
&
739%$7
73*1'
/
X+
$17
8
'$
933 $
6:B&/. &
3B
%
6:',2 '
;7$/.P )
*1'
)
3B
%
3B
&
3B
(
3B
%
;7$/.S )
5),2S $
*1'
&
3B
&
*1'
'
5),2P $
567
(
3B
'
9%$79 )
*1'
'
3B
'
3B
(
3B
(
9%$79 (
6:,7&+ )
3B
'
3B
&
;7$/0P $
;7$/0S %
9'&'& )
9'&'&B5) $
9%$7B5) (
*1'
$
*1'
%
&
X)
<
0+]
%7
9&RLQ
&
73933
X)
X)
+]
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 144 Final - January 29, 2015 v3.1
Table 280: Absolute maximum ratings
Parameter Description Conditions Min Typ Max Unit
VPIN(LIM)(defaul
t)
limiting voltage on a pin Voltage between pin and
GND
(Note 7)
-0.1 min{3.6,
VBAT_RF
+0.2}
V
TSTG storage temperature -50 150 °C
tR(SUP) supply rise time Power supply rise time 100 ms
VBAT(LIM)(VBA
T1V)
limiting battery supply
voltage
Supply voltage on
VBAT1V in a boost con-
verter application
(VBAT3V is second out-
put of boost-converter in
this case)
(Note 7)
-0.1 3.6 V
VBAT(LIM)(VBA
T3V)
limiting battery supply
voltage
Supply voltage on
VBAT3V and VBAT_RF
in a buck-converter
application, pin VBAT1V
is connected to ground
(Note 7)
-0.1 3.6 V
VPIN(LIM)(1V2) limiting voltage on a pin XTAL32Km, XTAL16Mp,
XTAL16Mm
(Note 7)
-0.2 min(1.2,V
BAT_RF+
0.2)
V
VPIN(LIM)(VDC
DC_RF)
limiting voltage on the
VDCDC_RF pin
Supply voltage on
VDCDC_RF
(Note 7)
-0.2 min(2,VBA
T_RF+0.2
)
V
VPIN(LIM)(XTAL
32Kp)
limiting voltage on a pin XTAL32Kp -0.2 min(1.5,V
BAT_RF+
0.2)
V
VESD(HBM)(WL
CSP34)
electrostatic discharge
voltage (Human Body
Model)
2000 V
VESD(HBM)(QF
N40)
electrostatic discharge
voltage (Human Body
Model)
4000 V
VESD(HBM)(QF
N48)
electrostatic discharge
voltage (Human Body
Model)
4000 V
VESD(MM)(WLC
SP34)
electrostatic discharge
voltage (Machine Model)
200 V
VESD(MM)(QFN
40)
electrostatic discharge
voltage (Machine Model)
200 V
VESD(MM)(QFN
48)
electrostatic discharge
voltage (Machine Model)
200 V
VESD(CDM)(WL
CSP34)
electrostatic discharge
voltage (Charged Device
Model)
500 V
VESD(CDM)(QF
N40)
electrostatic discharge
voltage (Charged Device
Model)
1000 V
VESD(CDM)(QF
N48)
electrostatic discharge
voltage (Charged Device
Model)
1000 V
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 145 Final - January 29, 2015 v3.1
Note 7: The device should not be exposed for prolonged periods of time to voltages between the Recommended Operating Conditions and the
Absolute Maximum Ratings range.
Note 8: Cold boot should not be performed if voltage is less than 2.5 V because of possible corruption during OTP data mirroring. Trim values pro-
grammed in the OTP as well as the application image, should be copied into RAM while VBAT3V >= 2.5 V.
Table 281: Recommended operating conditions
Parameter Description Conditions Min Typ Max Unit
VPP programming voltage Supply voltage on pin
VPP during OTP pro-
gramming; TJ 50 C
6.6 6.7 6.8 V
VBAT(VBAT1V) battery supply voltage Supply voltage on
VBAT1V in a boost con-
verter application
(VBAT3V is second out-
put of boost-converter in
this case)
0.9 3.3 V
VBAT(VBAT3V) battery supply voltage Supply voltage on
VBAT3V and VBAT_RF
in a buck-converter
application, pin VBAT1V
is connected to ground
2.35
(Note 8)
3.3 V
VPIN(default) voltage on a pin Voltage between pin and
GND
0min(3.3,V
BAT_RF+
0.2)
V
VPIN(1V2) voltage on a pin XTAL32Km, XTAL16Mp,
XTAL16Mm
01.2 V
VPIN(VDCDC_
RF)
voltage on a pin Supply voltage on
VDCDC_RF
0 2 V
TAambient temperature -40 85 °C
Table 282: DC characteristics
Parameter Description Conditions Min Typ Max Unit
IBAT(DP_SLP)_
BOOST_1kB
battery supply current Boost configuration in
deep-sleep with 1 kB
retention RAM active,
running from RC32K
oscillator at lowest fre-
quency
0.48 A
IBAT(DP_SLP)_
BOOST_2kB
battery supply current Boost configuration in
deep-sleep with 2 kB
retention RAM active,
running from XTAL32K
oscillator
0.55 A
IBAT(DP_SLP)_
BOOST_8kB
battery supply current Typical boost-applica-
tion in deep-sleep with 8
kB retention RAM active,
running from XTAL32K
oscillator
0.7 2A
IBAT(EXT_SLP)
_BOOST_43K
B
battery supply current Typical boost-applica-
tion in extended-sleep
mode with 42 kB (Sys-
RAM) and 1 kB
(RetRAM) retained
1.37 A
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 146 Final - January 29, 2015 v3.1
IBAT(EXT_SLP)
_BOOST_50kB
battery supply current Typical boost-applica-
tion in extended-sleep
mode with 42 kB (Sys-
RAM) and 8 kB
(RetRAM) retained
1.5 3A
IBAT(DP_SLP)_
BUCK_1kB
battery supply current Buck configuration in
deep-sleep with 1 kB
retention RAM active,
running from RC32K
oscillator at lowest fre-
quency
0.4 A
IBAT(DP_SLP)_
BUCK_2kB
battery supply current Buck configuration in
deep-sleep with 2 kB
retention RAM active,
running from XTAL32K
oscillator
0.45 A
IBAT(DP_SLP)_
BUCK_8kB
battery supply current Typical buck-application
in deep-sleep with 8 kB
retention RAM active,
running from XTAL32K
oscillator
0.6 2A
IBAT(EXT_SLP)
_BUCK_43KB
battery supply current Typical buck-application
in extended-sleep mode
with 42 kB (SysRAM)
and 1 kB (RetRAM)
retained
1.2 A
IBAT(EXT_SLP)
_BUCK_50kB
battery supply current Typical buck-application
in extended-sleep mode
with 42 kB (SysRAM)
and 8 kB (RetRAM)
retained
1.4 3A
IBAT(ACT_RX)
_BOOST
battery supply current Typical application with
boost converter and
receiver active
13.4 16 mA
IBAT(ACT_TX)_
BOOST
battery supply current Typical application with
boost converter and
transmitter active
12.4 15 mA
IBAT(ACT_RX)
_BUCK
battery supply current Typical application with
buck converter and
receiver active
5.1 6mA
IBAT(ACT_TX)_
BUCK
battery supply current Typical application with
buck converter and
transmitter active
4.8 6mA
Table 283: Timing characteristics
Parameter Description Conditions Min Typ Max Unit
tSTA(BOOST) startup time Boost-mode; time from
deep-sleep to software
start.
Typical application, run-
ning from retention RAM
on 16 MHz RC oscillator
1.2
(Note 9)
ms
Table 282: DC characteristics
Parameter Description Conditions Min Typ Max Unit
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 147 Final - January 29, 2015 v3.1
Note 9: Worst-case value under Normal Operating Conditions.
Note 10: Using the internal varicaps a wide range of crystals can be trimmed to the required tolerance.
Note 11: Maximum allowed frequency tolerance for compensation by the internal varicap trimming mechanism.
Note 12: Select a crystal which can handle a drive-level equal or more than this specification
tSTA(BUCK) startup time Buck-mode; time from
deep-sleep to software
start.
Typical application, run-
ning from retention RAM
on 16 MHz RC oscillator
1
(Note 9)
ms
Table 283: Timing characteristics
Parameter Description Conditions Min Typ Max Unit
Table 284: 16 MHz Crystal Oscillator: Recommended operating conditions
Parameter Description Conditions Min Typ Max Unit
fXTAL(16M) crystal oscillator fre-
quency
16 MHz
ESR(16M) equivalent series resist-
ance
100
CL(16M) load capacitance No external capacitors
are required
10 12 pF
C0(16M) shunt capacitance 5pF
fXTAL(16M) crystal frequency toler-
ance
After optional trimming;
including aging and tem-
perature drift
(Note 10)
-20 20 ppm
fX-
TAL(16M)UNT
crystal frequency toler-
ance
Untrimmed; including
aging and temperature
drift
(Note 11)
-40 40 ppm
PDRV(MAX)(16M
)
maximum drive power (Note 12) 100 W
VCLK(EXT)(16M) external clock voltage Only in case of an exter-
nal reference clock on
XTAL16Mp (XTAL16Mm
floating or connected to
mid-level 0.6 V)
11.2 V
N(EXTER-
NAL)16M
phase noise fC = 50 kHz
in case of an external
reference clock
-130 dBc/
Hz
Table 285: 16 MHz Crystal Oscillator: Timing characteristics
Parameter Description Conditions Min Typ Max Unit
tSTA(XTAL)(16M) crystal oscillator startup
time
0.5 2 3 ms
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 148 Final - January 29, 2015 v3.1
Note 13: Select a crystal that can handle a drive-level of at least this specification.
Note 14: This parameter is very much dependent on crystal parameters
Note 15: A low value will result in lowest power consumption, keep this value at 1 uF or 2 uF.
Table 286: 32 kHz Crystal Oscillator: Recommended operating conditions
Parameter Description Conditions Min Typ Max Unit
VCLK(EXT)(32K) external clock voltage peak-peak voltage of
external clock at
XTAL32Kp, pin
XTAL32Km floating.
note: XTAL32Kp is inter-
nally AC coupled
0.1 0.2 1.5 V
fXTAL(32k) crystal oscillator fre-
quency
frequency range for an
external clock
(for a crystal, use either
32.000 kHz or 32.768
kHz)
10 32.768 100 kHz
ESR(32k) equivalent series resist-
ance
100 k
CL(32k) load capacitance no external capacitors
are required for a 6 pF or
7 pF crystal
6 7 9 pF
C0(32k) shunt capacitance 1 2 pF
fXTAL(32k) crystal frequency toler-
ance (including aging)
Timing accuracy is domi-
nated by crystal accu-
racy. A much smaller
value is preferred
-250 250 ppm
PDRV(MAX)(32k) maximum drive power (Note 13) 0.1 W
Table 287: 32 kHz Crystal Oscillator: Timing characteristics
Parameter Description Conditions Min Typ Max Unit
tSTA(XTAL)(32k) crystal oscillator startup
time
Typical application, time
until 1000 clocks are
detected
(Note 14)
0.4 s
Table 288: DC-DC converter: Recommended operating conditions
Parameter Description Conditions Min Typ Max Unit
Leffective inductance 1.5 2.2 3H
COUT(VDCDC) effective load capaci-
tance
VDCDC and VDDCRF
combined
(Note 15)
0.5 110 F
COUT(VBAT3V) effective load capaci-
tance
VBATRF and VBAT3V
combined are the sec-
ond output of the boost-
converter
(Note 15)
0.5 110 F
Table 289: DC-DC converter: DC characteristics
Parameter Description Conditions Min Typ Max Unit
VO(BUCK) output voltage default settings 1.41 V
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 149 Final - January 29, 2015 v3.1
Note 16: When VBAT1V > VDCDC_nominal, VDCDC will follow VBAT1V.
VO(BOOST) output voltage default settings, VDCDC 1.41 V
CONV_MAX(BU
CK)
maximum conversion
efficiency
86 %
CONV_MAX(BO
OST)
maximum conversion
efficiency
80 %
VO/
VI(BUCK)
line regulation 2.35 V VBAT3V 3.3
V
-2 0.7 2%/V
VO/
VI(BOOST)
line regulation 0.9 V VBAT1V 1.2 V
(Note 16)
-2 1 4 %/V
VO/IL(BUCK) load regulation VBAT3V = 2.5 V -0.2 -0.02 0.2 %/mA
VO/
IL(BOOST)
load regulation VBAT1V = 1.2 V -0.2 -0.07 0.2 %/mA
VRPL(BUCK) ripple voltage buck mode; RMS ripple
voltage
5mV
VRPL(BOOST) ripple voltage VBAT1V 1.2 V, boost
mode; RMS ripple volt-
age
(Note 16)
8mV
Table 289: DC-DC converter: DC characteristics
Parameter Description Conditions Min Typ Max Unit
Table 290: Digital Input/Output: DC characteristics
Parameter Description Conditions Min Typ Max Unit
VIH HIGH level input voltage 0.84 V
VIL LOW level input voltage 0.36 V
VIH(RST) HIGH level input voltage RST pin 0.84 V
VIL(RST) LOW level input voltage RST pin 0.36 V
VOH(VBAT1V) HIGH level output volt-
age
Iout = -250 A, VBAT3V
= 2.35 V, VBAT1V = 0.9
V
0.72 V
VOH(VBAT3V) HIGH level output volt-
age
Iout = -4.8 mA, VBAT3V
= 2.35 V, VBAT1V = 0 V
1.88 V
VOL(VBAT1V) LOW level output voltage Iout = 250 A, VBAT3V
= 2.35 V, VBAT1V = 0.9
V
0.18 V
VOL(VBAT3V) LOW level output voltage Iout = 4.8 mA, VBAT3V =
2.35 V, VBAT1V = 0 V
0.47 V
IIH HIGH level input current Vin = VBAT3V = 2.5 V -1 1A
IIL LOW level input current Vin = VSS = 0 V -1 1A
IIH(PD) HIGH level input current Vin = VBAT3V = 2.5 V 50 150 A
IIL(PU) LOW level input current Vin = VSS = 0 V -150 -50 A
IIH(RST) HIGH level input current RST pin, V(RST) = 1.2 V 25 75 A
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 150 Final - January 29, 2015 v3.1
Note 17: The DCDC-converter efficiency is assumed to be 100 % to enable benchmarking of the radio currents at battery supply domain (VBAT3V =
3 V).
Table 291: General purpose ADC: Recommended operating conditions
Parameter Description Conditions Min Typ Max Unit
NBIT(ADC) number of bits (resolu-
tion)
10 bit
Table 292: General purpose ADC: DC characteristics
Parameter Description Conditions Min Typ Max Unit
VI(ZS) zero-scale input voltage single-ended, calibrated
at zero input
-2.5 02.5 mV
VI(FS) full-scale input voltage single-ended, calibrated
at zero input
1150 1180 1250 mV
VI(FSN) negative full-scale input
voltage
differential, calibrated at
zero input
-1180 mV
VI(FSP) positive full-scale input
voltage
differential, calibrated at
zero input
1180 mV
INL integral non-linearity -2 2LSB
DNL differential non-linearity -2 2LSB
Table 293: General purpose ADC: Timing characteristics
Parameter Description Conditions Min Typ Max Unit
tCONV(ADC) conversion time Excluding initial settling
time of the LDO and the
3x-attenuation (if used):
LDO settling time is 20
s (max), 3x-attenuation
settling time = 1 s (max)
Using internal ADC-clock
(~200 MHz)
0.25 0.4 s
Table 294: Radio: DC characteristics
Parameter Description Conditions Min Typ Max Unit
IBAT(RF)RX battery supply current receive mode; radio
receiver and synthesizer
active; DCDC converter
assumed ideal; TA = 25
°C
(Note 17)
3.7 4.3 mA
IBAT(RF)TX battery supply current transmit mode; radio
transmitter and synthe-
sizer active; DCDC con-
verter assumed ideal; TA
= 25 °C
(Note 17)
3.4 4mA
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 151 Final - January 29, 2015 v3.1
Table 295: Radio: AC characteristics
Parameter Description Conditions Min Typ Max Unit
PSENS(CLEAN) sensitivity level DC-DC converter ena-
bled; Dirty Transmitter
disabled; TA = 25 °C;
PER = 30.8 %
(Note 18)
-93 dBm
PSENS sensitivity level Normal Operating Condi-
tions; DC-DC converter
enabled; TA = 25 °C;
PER = 30.8 %
(Note 18)
-92.5 dBm
PI(max) input power level DC-DC converter disa-
bled; TA = 25 C; PER
30.8 %
(Note 18)
10 dBm
PINT(IMD) intermodulation distor-
tion interferer power
level
worst case interferer
level @ f1, f2 with 2f1-f2 =
f0, |f1-f2| = n MHz and n =
3,4,5; PWANTED = -64
dBm @ f0; PER = 30.8
%; TA = 25 °C
(Note 20)
-35 -31 dBm
CIR(0) carrier to interferer ratio n = 0; interferer @ f1 = f0
+ n*1 MHz; TA = 25 °C
(Note 21)
721 dB
CIR(1) carrier to interferer ratio n = ±1; interferer @ f1 =
f0 + n*1 MHz; TA = 25 °C
(Note 21)
-3 15 dB
CIR(P2) carrier to interferer ratio n = +2 (image fre-
quency); interferer @ f1
= f0 + n*1 MHz; TA = 25
C
(Note 21)
-20 -9 dB
CIR(M2) carrier to interferer ratio n = -2; interferer @ f1 =
f0 + n*1 MHz; TA = 25 C
(Note 21)
-30 -17 dB
CIR(P3) carrier to interferer ratio n = +3 (image frequency
+ 1 MHz); interferer @ f1
= f0 + n*1 MHz; TA = 25
C
(Note 21)
-30 -15 dB
CIR(M3) carrier to interferer ratio n = -3; interferer @ f1 =
f0 + n*1 MHz; TA = 25 C
(Note 21)
-35 -27 dB
PBL(I) blocker power level 30 MHz fBL 2000
MHz; PWANTED = -67
dBm; TA = 25 °C
(Note 22)
-5 dBm
PBL(II) blocker power level 2003 MHz fBL 2399
MHz; PWANTED = -67
dBm; TA = 25 °C
(Note 22)
-15 dBm
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 152 Final - January 29, 2015 v3.1
PBL(III) blocker power level 2484 MHz fBL 2997
MHz; PWANTED = -67
dBm; TA = 25 C
(Note 22)
-15 dBm
CIR(4) carrier to interferer ratio |n| >= 4 (any other BLE
channel); interferer @ f1
= f0 + n*1 MHz; TA = 25
°C
(Note 21)
-37 -27 dB
PBL(IV) blocker power level 3000 MHz fBL 12.75
GHz; PWANTED = -67
dBm; TA = 25 C
(Note 22)
-5 dBm
PRSSI(min) RSSI power level absolute power level for
RXRSSI[7:0] = 0; TA =
25 °C
(Note 23)
-115 -112 -109 dBm
PRSSI(max) RSSI power level upper limit of monoto-
nous range; TA = 25 °C
-26 -19 dBm
LACC(RSSI)BO
OST
level accuracy tolerance of 5 % to 95 %
confidence interval of
PRF: when RXRSSI[7:0]
= X, 50 < X < 175; burst
mode 1500 packets; TA
= 25 °C; DC-DC con-
verter in BOOST mode
0 3 dB
LACC(RSSI)BU
CK
level accuracy tolerance of 5 % to 95 %
confidence interval of
PRF: when RXRSSI[7:0]
= X, 50 < X < 175; burst
mode 1500 packets; TA
= 25 °C; DC-DC con-
verter in BUCK mode
0 2 dB
LRES(RSSI) level resolution gradient of monotonous
range for RXRSSI[7:0] =
X, 50 < X < 175; burst
mode 1500 packets; TA
= 25C
0.46 0.474 0.485 dB/
LSB
ACP(2M) adjacent channel power
level
fOFFSET = 2 MHz; TA =
25C
(Note 24)
-53 -50 dBm
ACP(2M)(EOC) adjacent channel power
level
fOFFSET = 2 MHz; -40C
TA +85C
(Note 24)
-53 -47 dBm
ACP(3M) adjacent channel power
level
fOFFSET 3 MHz; TA =
25C
(Note 24)
-57 -55 dBm
ACP(3M)(EOC) adjacent channel power
level
fOFFSET 3 MHz; -40C
TA +85C
(Note 24)
-57 -47 dBm
Table 295: Radio: AC characteristics
Parameter Description Conditions Min Typ Max Unit
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 153 Final - January 29, 2015 v3.1
Note 18: Measured according to Bluetooth® Low Energy Test Specification RF-PHY.TS/4.0.1, section 6.4.1.
Note 19: Measured according to Bluetooth® Low Energy Test Specification RF-PHY.TS/4.0.1, section 6.4.2.
Note 20: Measured according to Bluetooth® Core Technical Specification document, version 4.0, volume 6, section 4.4. Published value is for n =
IXIT = 4 . IXIT = 5 gives the same results, IXIT = 3 gives results that are 5 dB lower.
Note 21: Measured according to Bluetooth® Core Technical Specification document, version 4.0, volume 6, section 4.2.
Note 22: Measured according to Bluetooth® Core Technical Specification document, version 4.0, volume 6, section 4.3. Due to limitations of the
measurement equipment, levels of -5 dBm should be interpreted as > -5 dBm.
Note 23: PRF = PRSSI(min) + LRES(RSSI) x RXRSSI[7:0] ± LACC(RSSI). Thanks to constant gain biasing of RF part in the receiver, the RSSI can
be used to estimate absolute power levels, rather than mere level changes. Even across the full temperature range the variation is limited.
Note 24: Measured according to Bluetooth® Low Energy Test Specification RF-PHY.TS/4.0.1, section 6.2.3.
Note 25: To activate the "Near Field Mode", program address 0x50002418 with the value 0x0030.
Note 26: Maximum recommended connection interval (including slave latency) for the RCX usage is 2 s.
POoutput power level VDD = 3 V; maximum
gain; TA = 25 °C
-2 -1 0dBm
PO(HD2) output power level (sec-
ond harmonic)
VDD = 3 V; maximum
gain; TA = 25 C
-54 -40 dBm
PO(HD3) output power level (third
harmonic)
VDD = 3 V; maximum
gain; TA = 25 C
-56 -40 dBm
PO(HD4) output power level
(fourth harmonic)
VDD = 3 V; maximum
gain; TA = 25 C
-70 -40 dBm
PO(HD5) output power level (fifth
harmonic)
VDD = 3 V; maximum
gain; TA = 25 C
-70 -40 dBm
PO(NFM) output power level in
'Near Field Mode'
VDD = 3 V; maximum
gain; TA = 25 °C
(Note 25)
-25 -20 -15 dBm
Table 295: Radio: AC characteristics
Parameter Description Conditions Min Typ Max Unit
Table 296: Stable low frequency RCX Oscillator: Timing characteristics
Parameter Description Conditions Min Typ Max Unit
fRC(RCX) RCX oscillator frequency default setting, buck
mode only
510 40 kHz
fRC(RCX) RCX oscillator fre-
quency drift
buck mode only
(Note 26)
-500 500 ppm
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 154 Final - January 29, 2015 v3.1
6. Package information
6.1 MOISTURE SENSITIVITY LEVEL (MSL)
The MSL is an indicator for the maximum allowable
time period (floor life time) in which a moisture sensi-
tive plastic device, once removed from the dry bag, can
be exposed to an environment with a maximum tem-
perature of 30 °C and a maximum relative humidity of
60 % RH. before the solder reflow process.
WLCSP packages are qualified for MSL 1.
QFN packages are qualified for MSL 3.
6.2 WLCSP HANDLING
Manual handling of WLCSP packages should be
reduced to the absolute minimum. In cases where it is
still necessary, a vacuum pick-up tool should be used.
In extreme cases plastic tweezers could be used, but
metal tweezers are not acceptable, since contact may
easily damage the silicon chip.
Removal will cause damage to the solder balls and
therefore a removed sample cannot be reused.
WLCSP is sensitive to visible and infrared light. Pre-
cautions should be taken to properly shield the chip in
the final product.
6.3 SOLDERING INFORMATION
Refer to the JEDEC standard J-STD-020 for relevant
soldering information.
This document can be downloaded from http://
www.jedec.org
MSL Level Floor Life Time
MSL 3 168 hours
MSL 1 Unlimited at 30°C/85%RH
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 155 Final - January 29, 2015 v3.1
6.4 PACKAGE OUTLINES
Figure 13 QFN48 Package Outline Drawing
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 156 Final - January 29, 2015 v3.1
Figure 14 QFN40 Package Outline Drawing
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 157 Final - January 29, 2015 v3.1
Figure 15 WLCSP34 Package Outline Drawing
DA14580 Low Power Bluetooth Smart SoC
© 2014 Dialog Semiconductor 158 Final - January 29, 2015 v3.1
Status definitions
Disclaimer
Information in this document is believed to be accurate and reliable. However, Dialog Semiconductor does not give
any representations or warranties, expressed or implied, as to the accuracy or completeness of such information.
Dialog Semiconductor furthermore takes no responsibility whatsoever for the content in this document if provided by
any information source outside of Dialog Semiconductor.
Dialog Semiconductor reserves the right to change without notice the information published in this document, includ-
ing without limitation the specification and the design of the related semiconductor products, software and applica-
tions.
Applications, software, and semiconductor products described in this document are for illustrative purposes only.
Dialog Semiconductor makes no representation or warranty that such applications, software and semiconductor
products will be suitable for the specified use without further testing or modification. Unless otherwise agreed in writ-
ing, such testing or modification is the sole responsibility of the customer and Dialog Semiconductor excludes all lia-
bility in this respect.
Customer notes that nothing in this document may be construed as a license for customer to use the Dialog Semi-
conductor products, software and applications referred to in this document. Such license must be separately sought
by customer with Dialog Semiconductor.
All use of Dialog Semiconductor products, software and applications referred to in this document are subject to
Dialog Semiconductor's Standard Terms and Conditions of Sale, unless otherwise stated.
© Dialog Semiconductor. All rights reserved.
RoHS compliance
Dialog Semiconductor complies to European Directive 2001/95/EC and from 2 January 2013 onwards to European
Directive 2011/65/EU concerning Restriction of Hazardous Substances (RoHS/RoHS2). Dialog Semiconductor’s
statement on RoHS can be found on the customer portal https://support.diasemi.com/. RoHS certificates from our
suppliers are available on request.
Version Datasheet status Product status Definition
1.<n> Target Development This datasheet contains the design specifications for prod-
uct development. Specifications may change in any manner
without notice.
2.<n> Preliminary Qualification This datasheet contains the specifications and preliminary
characterisation data for products in pre-production. Speci-
fications may be changed at any time without notice in order
to improve the design.
3.<n> Final Production This datasheet contains the final specifications for products
in volume production. The specifications may be changed
at any time in order to improve the design, manufacturing
and supply. Relevant changes will be communicated via
Customer Product Notifications.
4.<n> Obsolete Archived This datasheet contains the specifications for discontinued
products. The information is provided for reference only.
United Kingdom (Headquarters)
Dialog Semiconductor PLC
Phone: +44 1793 757700
Germany
Dialog Semiconductor GmbH
Phone: +49 7021 805-0
The Netherlands
Dialog Semiconductor B.V.
Phone: +31 73 640 8822
Email
enquiry@diasemi.com
Contacting Dialog Semiconductor
North America
Dialog Semiconductor Inc.
Phone: +1 408 845 8500
Japan
Dialog Semiconductor K. K.
Phone: +81 3 5425 4567
Taiwan
Dialog Semiconductor Taiwan
Phone: +886 281 786 222
Web site
www.dialog-semiconductor.com
Singapore
Dialog Semiconductor Singapore
Phone: +65 64 849929
China
Dialog Semiconductor China
Phone: +86 21 5178 2561
Korea
Dialog Semiconductor Korea
Phone: +82 2 3469 8291
