1
1000 Bytes
RAM
Register File
ALU
MicroCode
Engine
Interrupt
Controller PTS
Memory
Controller
Queue
Watchdog
Timer PWM
PORT2
Serial
Port HSIO and
Timers
HSI HSO
Alternate
Functions
CPU
Alternate
Functions
PORT1
HOLD
HLDA
BREQ
PWM1
PWM2
Control
Signals
Address /Data Bus
Figure 1. UT80CRH196KDS Microcontroller
FirstPass
Core IP
PORT0
EXTINT
ECB0-
ECB5
FEATURES
q20MHz 16-bit Microcontroller compatible with industry
standard’s MCS-96 ISA
- Register to Register Architecture
- 1000 Byte Register RAM
qThree 8-bit I/O Ports
qOn-board Interrupt Controller
qThree Pulse-Width Modulated Outputs
qHigh Speed I/O
qUART Serial Port
qDedicated Baud Rate Generator
qSoftware and Hardware Timers
- 16-Bit Watchdog Timer, Four 16-Bit Software Timers
- Three 16-Bit Counter/Timers
qRadiation-hardened process and design; total dose
irradiation testing to MIL-STD-883 Method 1019
- Total-dose: 300K rads(Si)
- Onset LET Threshold: 25MeV-cm2/mg
- Saturated cross section: 6.0E-7 cm2/bit
- Latchup immune (LET > 128 MeV-cm2/mg)
q Error detection and correction for external memory accesses
q QML Q and QML V compliant part
q Standard Microcircuit Drawing 5962-02523
INTRODUCTION
The UT80CRH196KDS is compatible with industry standard’s
MCS-96 instruction set. The UT80CRH196KDS is supported
by commercial hardware and software development tools. Built
on UTMC’s Commercial RadHardTM epitaxial CMOS
technology, the microcontroller is hardened against ionizing
dose and charged particles. The microcontroller’s on-board
1000 byte scratch-pad SRAM and flip-flops can withstand
charged particles with energies up to 25 MeV-cm2/mg.
The UT80CRH196KDS accesses instruction code and data via
a 16-bit address and data bus. The 16-bit bus allows the
microcontroller to access 128K bytes of instruction/data
memory. Integrated software and hardware timers, high speed
I/O, pulse width modulation circuitry, and UART make the
UT80CRH196KDS ideal for control type applications. The
CPU’s ALU supports byte and word adds and subtracts, 8 and
16 bit multiplies, 32/16 and 16/8 bit divides, as well as
increment, decrement, negate, compare, and logical operations.
The UT80CRH196KDS’s interrupt controller prioritizes and
vectors 18 interrupt events. Interrupts include normal interrupts
and special interrupts. To reduce power consumption, the
microcontroller supports software invoked idle and power down
modes. The UT80CRH196KDS is packaged in a 68-lead quad
flatpack.
Standard Products
UT80CRH196KDS Microcontroller
Datasheet
May, 2003
2
1.0 SIGNAL DESCRIPTION
Port 0 (P0.0 - P0.7): Port 0 is an 8-bit input only port when used
in its default mode. When configured for their alternate function,
five of the bits are bi-directional EDAC check bits as shown in
Table 1.
Port 1 (P1.0 - P1.7): Port 1 is an 8-bit, quasi-bidirectional, I/O
port. All pins are quasi-bidirectional unless the alternate
function is selected per Table 2. When the pins are configured
for their alternate functions, they act as standard I/O, not quasi-
bidirectional.
Port 2 (P2.0 - P2.7): Port 2 is an 8-bit, multifunctional, I/O port.
These pins are shared with timer 2 functions, serial data I/O and
PWM0 output, per Table 3.
AD0-AD7: The lower 8-bits of the multiplexed address/data
bus. The pins on this port are bidirectional during the data phase
of the bus cycle.
AD8-AD15: The upper 8-bits of the multiplexed address/data
bus. The pins on this port are bidirectional during the data phase
of the 16-bit bus cycle. When running in 8-bit bus width, these
pins are non-multiplexed, dedicated upper address bit outputs.
HSI: Inputs to the High Speed Input Unit. Four HSI pins are
available: HSI.0, HSI.1, HSI.2, and HSI.3. Two of these pins
(HSI.2 and HSI.3) are shared with the HSO Unit. Two of these
pins (HSI.0 and HSI.1) have alternate functions for Timer 2.
HSO: Outputs from the High Speed Output Unit. Six HSO pins
are available: HSO.0, HSO.1, HSO.2, HSO.3, HSO.4, and
HSO.5. Pins HSO.4 and HSO.5 are shared with pins HSI.2 and
HSI.3 of the HSI Unit respectively.
Table 1. Port 0 Alternate Functions
Port Pin Alternate
Name Alternate Function
P0.0-P0.3,
P0.6 ECB0-ECB4 Error Detection & Correction
Check Bits
P0.4
P0.5 Input Port Pins
P0.7 EXTINT Setting IOC1.1=1 will allow P0.7
to be used for EXTINT (INT07)
Table 2. Port 1 Alternate Functions
Port
Pin Alternate
Name Alternate Function
P1.0 P1.0 I/O Pin
P1.1 P1.1 I/O Pin
P1.2 P1.2 I/O Pin
P1.3 PWM1 Setting IOC3.2=1 enables P1.3 as
the Pulse Width Modulator
(PWM1) output pin.
P1.4 PWM2 Setting IOC3.3=1 enables P1.4 as
the Pulse Width Modulator
(PWM2) output pin.
P1.5 BREQ Bus Request, output activated
when the bus controller has a
pending external memory cycle.
P1.6 HLDA Bus Hold Acknowledge, output
indicating the release of the bus.
P1.7 HOLD Bus Hold, input requesting control
of the bus.
Table 3. Port 2 Alternate Functions
Port
Pin Alternate
Name Alternate Function
P2.0 TXD Transmit Serial Data.
P2.1 RXD Receive Serial Data.
P2.2 EXTINT External interrupt. Clearing
IOC1.1 will allow P2.2 to be
used for EXTINT (INT07)
P2.3 T2CLK Timer 2 clock input and Serial
port baud rate generator input.
P2.4 T2RST Timer 2 Reset
P2.5 PWM0 Pulse Width Modulator
output 0
P2.6 T2UP-DN Controls the direction of the
Timer 2 counter. Logic High
equals count down. Logic low
equals count up.
P2.7 T2CAPTURE A rising edge on P2.7 causes
the value of Timer 2 to be
captured into this register, and
generates a Timer 2 Capture
interrupt (INT11).
3
1.1 Hardware Interface
1.1.1 Interfacing with External Memory
The UT80CRH196KDS can interface with a variety of external
memory devices. It supports either a fixed 8-bit bus width or a
dynamic 8-bit/16-bit bus width, internal READY control for
slow external memory devices, a bus-hold protocol that enables
external devices to take over the bus, and several bus-control
modes. These features provide a great deal of flexibility when
interfacing with external memory devices.
1.1.1.1 Chip Configuration Register
The Chip Configuration Register (CCR) is used to initialize the
UT80CRH196KDS immediately after reset. The CCR is fetched
from external address 2018H (Chip Configuration Byte) after
removal of the reset signal. The Chip Configuration Byte (CCB)
is read as either an 8-bit or 16-bit word depending on the value
of the BUSWIDTH pin. The composition of the bits in the CCR
are shown in Table 4.
There are 8 configuration bits available in the CCR. However,
bits 7 and 6 are not used by the UT80CRH196KDS. Bits 5 and
4 comprise the READY mode control which define internal
limits for waitstates generated by the READY pin. Bit 3 controls
the definition of the ALE/ADV pin for system memory controls
while bit 2 selects between the different write modes. Bit 1
selects whether the UT80CRH196KDS will use a dynamic 16-
bit bus or whether it will be locked in as an 8-bit bus. Finally,
Bit 0 enables the Power Down mode and allows the user to
disable this mode for protection against inadvertent power
downs.
1.1.1.2 Bus Width and Memory Configurations
The UT80CRH196KDS external bus can operate as either an 8-
bit or 16-bit multiplexed address/data bus (see figure 2). The
value of bit 1 in the CCR determines the bus operation. A logic
low value on CCR.1 locks the bus controller in 8-bit bus mode.
If, however, CCR.1 is a logic high, then the BUSWIDTH signal
is used to decide the width of the bus. The bus is 16 bits wide
when the BUSWIDTH signal is high, and is 8 bits when the
BUSWIDTH signal is low.
1.1.2 Reset
To reset the UT80CRH196KDS, hold the RESET pin low for
at least 16 state times after the power supply is within tolerance
and the oscillator has stabilized. Resets following the power-up
reset may be asserted for at least one state time, and the device
will turn on a pull-down transistor for 16 state times. This
enables the RESET signal to function as the system reset. The
reset state of the external I/O is shown in Table 9, and the register
reset values are shown in Table 8.
1.1.3 Instruction Set
The instruction set for the UT80CRH196KDS is compatible
with the industry standard MCS-96 instruction set used on the
8XC196KDS.
Notes:
1.The first instruction read following reset will be from location 2080h. All other external memory can be used as instruction and/or data memory.
Table 4. Chip Configuration Register
Bit Function
7N/A
6N/A
5IRC1 - Internal READY Mode Control
4IRC0 - Internal READY Mode Control
3Address Valid Strobe Select (ALE/ADV)
2Write Strobe Mode Select (WR and BHE/WRL and WRH)
1Dynamic Bus Width Enable
0Enable Power Down Mode
Table 5. Memory Map
Memory Description Begin End
External Memory102080H 0FFFFH
Reserved 0205EH 0207FH
PTS Vectors 02040H 0205DH
Upper Interrupt Vectors 02030H 0203FH
Reserved 02020H 0202FH
Reserved 02019H 0201FH
Chip Configuration Byte 02018H 02018H
Reserved 02014H 02017H
Lower Interrupt Vectors 02000H 02013H
External Memory 00400H 1FFFH
Internal Memory (RAM) 0001AH 003FFH
Special Function Registers 00000H 00019H
4
Table 6. Interrupt Vector Sources, Locations, and Priorities
Number Interrupt Vector Source(s) Interrupt
Vector
Location
PTS
Vector
Location
Priority1
(0 is the
Lowest
Priority)
Special Unimplemented
Opcode Unimplemented Opcode 2012h N/A N/A
Special Software Trap Software Trap 2010h N/A N/A
INT 15 NMI2NMI 203Eh N/A 15
INT 14 HSI FIFO Full HSI FIFO Full 203Ch 205Ch 14
INT 13 EXTINT 12Port 2.2 203Ah 205Ah 13
INT 12 Timer 2 Overflow Timer 2 Overflow 2038h 2058h 12
INT 11 Timer 2 Capture2Timer 2 Capture 2036h 2056h 11
INT 10 HSI FIFO 4 HSI FIFO
Fourth Entry 2034h 2054h 10
INT 9 Receive RI Flag32032h 2052h 9
INT 8 Transmit TI Flag32030h 2050h 8
INT 7 EXTINT2Port 2.2 or Port 0.7 200Eh 204Eh 7
INT 6 Serial Port RI Flag and
TI Flag4200Ch 204Ch 6
INT 5 Software Timer Software Timer 0-3
Timer 2 Reset 200Ah 204Ah 5
INT 4 HSI.02HSI.0 Pin 2008h 2048h 4
INT 3 High Speed
Outputs Events on HSO.0 thru
HSO.5 Lines 2006h 2046h 3
INT 2 HSI Data Available HSI FIFO Full or
HSI Holding Reg.
Loaded
2004h 2044h 2
INT 1 EDAC Bit Error Single Bit Error
Single Bit Error OVF
Double Bit Error
2002h 2042h 1
INT 0 Timer Overflow Timer 1 or Timer 2 2000h 2040h 0
All of the previous maskable interrupts can be assigned to the PTS.
Any PTS interrupt has priority over all other maskable interrupts.
5
Notes:
1. The Unimplemented Opcode and Software Trap interrupts are not prioritized. The Interrupt Controller immediately services these interrupts when they are
asserted. NMI has the highest priority of all prioritized interrupts. Any PTS interrupt has priority over lower priority interrupts, and over all other maskable
interrupts. The standard maskable interrupts are serviced according to their priority number with INT0 has the lowest priority of all interrupts.
2. These interrupts can be configured to function as independent, external interrupts.
3. If the Serial interrupt is masked and the Receive and Transmit interrupts are enabled, the RI flag and TI flag generate separate Receive and Transmit interrupts.
4. If the Receive and Transmit interrupts are masked and the Serial interrupt is enabled, both RI flag and TI flag generate a Serial Port interrupt.
6
Notes:
1. For some functions that share a register address in HWindow0, the opposite access type (read/write) is available in HWindow 15 if
indicated by the three asterisks (***).
2. These registers are not available in the industry standard 8XC196KDS. Therefore, industry standard development software will not recognize these
mnemonics, and you will only be able to access them via their physical addresses.
Table 7. SFR Memory Mapping
Address HWin 0 Read HWin 0 Write HWin 1 HWin 151
019H Stack Pntr (hi) Stack Pntr (hi) Stack Pntr (hi) Stack Pntr (hi)
018H Stack Pntr (lo) Stack Pntr (lo) Stack Pntr (lo) Stack Pntr (lo)
017H IOS2 PWM0_CTRL PWM2_CTRL ***
016H IOS1 IOC1 PWM1_CTRL ***
015H IOS0 IOC0 EDAC-CS2***
014H WSR WSR WSR WSR
013H INT_MASK1 INT_MASK1 INT_MASK1 INT_MASK1
012H INT_PEND1 INT_PEND1 INT_PEND1 INT_PEND1
011H SP_STAT SP_CON RESERVED ***
010H PORT 2 PORT 2 RESERVED PSW2
00FH PORT 1 PORT 1 Timer 3(hi)2RESERVED
00EH PORT 0 BAUD RATE Timer 3(lo)2RESERVED
00DH Timer 2 (hi) Timer 2 (hi) WDT-SCALE2T2CAPTURE (hi)
00CH Timer 2 (lo) Timer 2 (lo) IOC3 T2CAPTURE (lo)
00BH Timer 1 (hi) IOC2 INT_PRI(hi)2***
00AH Timer 1 (lo) Watchdog INT_PRI(lo)2***
009H INT_PEND INT_PEND INT_PEND INT_PEND
008H INT_MASK INT_MASK INT_MASK INT_MASK
007H SBUF (RX) SBUF (TX) PTSSRV (hi) ***
006H HSI_status HSO_command PTSSRV (lo) ***
005H HSI_time(hi) HSO_time (hi) PTSSEL (hi) ***
004H HSI_time (lo) HSO_time (lo) PTSSEL (lo) ***
003H RESERVED HSI_mode RESERVED ***
002H RESERVED RESERVED RESERVED RESERVED
001H Zero_reg (hi) Zero_reg (hi) Zero-reg (hi) Zero_reg (hi)
000H Zero_reg (lo) Zero_reg (lo) Zero_reg (lo) Zero_reg (lo)
7
Table 8: Special Function Register Reset Values
Internal Register Binary Reset State Hexadecimal Reset
Value
Stack Pointer (SP) XXXX XXXX XXXX XXXX XXXX
I/O Status Register 2 (IOS2) 0000 0000 00
I/O Status Register 1 (IOS1) 0000 0000 00
I/O Status Register 0 (IOS0) 0000 0000 00
Window Select Register (WSR) 0000 0000 00
Interrupt Mask Register 1 (INT_MASK1) 0000 0000 00
Interrupt Pending Register 1
(INT_PEND1) 0000 0000 00
Serial Port Status Register (SP_STAT) 0000 1011 0B
Port 2 Register (PORT2) 110X XXX1 XX
Port 1 Register (PORT1) 1111 1111 FF
Port 0 Register (PORT0) XXXX XXXX XX
Timer 2 Value Register (TIMER2) 0000 0000 0000 0000 0000
Timer 1 Value Register (TIMER1) 0000 0000 0000 0000 0000
Interrupt Pending Register (INT_PEND) 0000 0000 00
Interrupt Mask Register (INT_MASK) 0000 0000 00
Receive Serial Port Register (SBUF
(RX)) 0000 0000 00
HSI Status Register (HSI_status) X0X0 X0X0 XX
HSI Time Register (HSI_time) XXXX XXXX XXXX XXXX XXXX
Zero Register (ZERO_REG) 0000 0000 0000 0000 0000
PWM0 Control Register (PWM0_CTRL) 0000 0000 00
I/O Control Register 1 (IOC1) 0010 0001 21
I/O Control Register 0 (IOC0) 0000 00X0 0X
Serial Port Control Register (SP_CON) 0000 1011 0B
Baud Rate Register (BAUD_RATE) 0000 0000 0000 0001 0001
I/O Control Register 2 (IOC2) X00X X000 XX
Watch Dog Timer Register (WATCH-
DOG) 0000 0000 00
8
Transmit Serial Port Buffer (SBUF (TX)) 0000 0000 00
HSO Command Register
(HSO_command) 0000 0000 00
HSO Time Register (HSO_time) 0000 0000 0000 0000 0000
HSI Mode Register (HSI_mode) 1111 1111 FF
PWM2 Control Register (PWM2_CTRL) 0000 0000 00
PWM1 Control Register (PWM1_CTRL) 0000 0000 00
EDAC Control and Status Register
(EDAC_CS) 0000 0000 00
Timer 3 Value Register (TIMER3) 0000 0000 0000 0000 0000
Watchdog Timer Prescaler
(WDT_SCALE) 0000 0000 00
I/O Control Register 3 (IOC3) 1111 0000 F0
Interrupt Priority Register (INT_PRI) 0000 0000 00
PTS Service Register (PTSSRV) 0000 0000 0000 0000 0000
PTS Select Register (PTSSEL) 0000 0000 0000 0000 0000
Timer 2 Capture Register
(T2CAPTURE) 0000 0000 0000 0000 0000
Program Counter (PC) 0010 0000 1000 0000 2080
Chip Configuration Register (CCR) XX10 1111 XF
Table 8: Special Function Register Reset Values
Internal Register Binary Reset State Hexadecimal Reset
Value
9
Table 9: External I/O Reset State
External I/O I/O Function After Reset I/O State During
Reset I/O State After Reset
Address/Data Bus (AD15:0) Address/Data Bus Pulled High Driven Output
ALE
ADV ALE Pulled High Driven Output
RD RD Pulled High Driven Output
WR
WRL WR Pulled High Driven Output
Port 0 (P0.0-P0.3; P0.6)
ECB(4:0) [P0.0-P0.3; P0.6] and
ECB(4:0) Undefined Inputs1Undefined I/O1,2
Port 0 (P0.4 and P0.5) P0.4 and P0.5 Undefined Inputs1Undefined Inputs1
Port 0 (P0.7)
EXTINT P0.7 Undefined Input1Undefined Input1
NMI NMI Pulled Down Pulled Down
HSI.0
T2RST HSI.0 Disabled Input1Disabled Input1
HSI.1
T2CLK HSI.1 Disabled Input1Disabled Input1
HSI.2/HSO.4 Undefined Disabled I/O1Disabled I/O1
HSI.3/HSO.5 Undefined Disabled I/O1Disabled I/O1
HSO.0 through HSO.3 HSO.0-HSO.3 Pulled Down Driven Low
Outputs
Port 1 (P1.0-P1.7)
PWM1; PWM2;
BREQ; HLDA; HOLD
P1.0-P1.7 Pulled Up Pulled Up
Port 2 (P2.0)
TXD TXD Pulled Up Driven High
Output
Port 2 (P2.1)
RXD RXD Undefined Input1Undefined Input1
Port 2 (P2.2)
EXTINT P2.2 and EXTINT Undefined Input1Undefined Input1
Port 2 (P2.3)
T2CLK P2.3 and T2CLK Undefined Input1Undefined Input1
Port 2 (P2.4)
T2RST P2.4 Undefined Input1Undefined Input1
10
Notes:
1. These pins must not be left floating. Input voltages must not exceed VDD during power-up.
2. Do not directly tie these pins to VDD or GND; if EDACEN goes low, they may be driven by the UT80CRH196KDS and bus contention may occur.
Port 2 (P2.5)
PWM0 PWM0 Pulled Down Driven Low Output
Port 2 (P2.6)
T2UP-DN P2.6 Pulled Up Pulled Up
Port 2 (P2.7)
T2CAPTURE P2.7 and T2CAPTURE Pulled Up Pulled Up
EDACEN EDACEN Undefined Input1Undefined Input1
ECB5/ADV_RD_WR ECB5/ADV_RD_WR Undefined I/O1Undefined I/O1,2
READY READY Undefined Input1Undefined Input1
BUSWIDTH BUSWIDTH Undefined Input1Undefined Input1
BHE
WRH BHE Pulled Up Driven Output
CLKOUT CLKOUT Driven Output Driven Output
INST INST Pulled Down Driven Output
RESET RESET Pulled Low by
System Pulled Up
Table 9: External I/O Reset State
External I/O I/O Function After Reset I/O State During
Reset I/O State After Reset
11
UT80CRH196KDSUT80CRH196KDS
Bus Control
16-Bit
Multiplexed
Address/Data
8-Bit
Multiplexed
Address/Data
8-Bit
Latched
Address High
Bus Control
AD0-AD15
AD0-AD7
AD8-AD15
16-Bit Bus 8-Bit Bus
Figure 2. Bus Width Options
12
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
9
8
7
6
5
4
3
2
1
68
67
66
65
64
63
62
61
UT80CRH196KDS
TOP VIEW
Figure 3. 68-pin Quad Flatpack Package
AD0
AD1
AD2
AD3
AD4
AD5
AD6
AD7
AD8
AD9
AD10
AD11
AD12
AD13
AD14
AD15
P2.3/T2CLK
HSI.3/HSO.5
HS0.0
HS0.1
BREQ/P1.5
HLDA/P1.6
HOLD/P1.7
T2UP-DN/P2.6
HS0.2
HS0.3
VSS
EDACEN
T2CAPTURE/P2.7
PWM0/P2.5
WR/WRL
BHE/WRH
T2RST/P2.4
READY
P0.7/EXTINT
P0.6/ECB0
P0.2/ECB1
P0.0/ECB2
P0.1/ECB3
P0.3/ECB4
NMI
ECB5/ADV_RD_WR
VDD
VSS
XTAL1
VSS
CLKOUT
BUSWIDTH
INST
ALE/ADV
RD
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
P0.5
P0.4
VSS
VDD
VSS
EXTINT/P2.2
RESET
RXD/P2.1
TXD/P2.0
P1.0
P1.1
P1.2
PWM1/P1.3
PWM2/P1.4
T2RST/HSI.0
T2CLK/HSI.1
HSI.2/HS0.4
13
Legend for I/O fields:
TO = TTL compatible output
TI = TTL compatible input
CI = CMOS only input
TUO = TTL compatible output
(internally pulled high)
TDO = TTL compatible output
(internally pulled low)
TUI = TTL compatible input
(internally pulled high)
TDI = TTL compatible input
(internally pulled low)
TB = TTL compatible bidirectional
TUQ = TTL compatible quasi-bidirectional
(internally pulled high)
TUB = TTL compatible bidirectional
(internally pulled high)
TUBS = TTL compatible bidirectional Schmitt
Trigger (internally pulled high)
PWR = +5V (VDD)
GND = OV (VSS)
Table 10: 68-lead Flat Pack Pin Descriptions
QFP Pin# I/O Name Active Description
1PWR VDD --- Digital supply voltage (+5V). There are 2 VDD pins, both of
which must be connected.
2TO ADV_RD_WR --- Advanced Read and Write. This pin has multiplexed functional-
ity: coincident with the Address/Data bus multiplexing. When
address information is output on the AD pins, ADV_RD_WR is
output. When data information is on the AD pins, ECB5 is an I/
O. ADV_RD_WR is output high for an external memory read
cycle, and low for an external memory write cycle.
TB ECB51-- EDAC Check Bit 5. Asserting the EDACEN pin will cause the
error detection and correction engine to pass the EDAC Check
Bit 5 through pin 2 of the UT80CRH196KDS during the data
phase of an external memory cycle.
3TDI NMI High Non-Maskable Interrupt. A positive transition causes a vector
through the NMI interrupt at location 203Eh. Assert NMI for at
least 1 state time to guarantee acknowledgment by the interrupt
controller.
4TI P0.3 --- Port 0 Pin 3. An input only port pin that is read at location 0Eh
in HWindow 0.
TB ECB41--- EDAC Check Bit 4. Asserting the EDACEN pin will cause the
error detection and correction engine to pass the EDAC Check
Bit 4 through pin 4 of the UT80CRH196KDS.
5TI P0.1 --- Port 0 Pin 1. An input only port pin that is read at location 0Eh
in HWindow 0.
TB ECB31--- EDAC Check Bit 3. Asserting the EDACEN pin will cause the
error detection and correction engine to pass the EDAC Check
Bit 3 through pin 5 of the UT80CRH196KDS.
14
6TI P0.0 --- Port 0 Pin 0. An input only port pin that is read at location 0Eh
in HWindow 0.
TB ECB21--- EDAC Check Bit 2. Asserting the EDACEN pin will cause the
error detection and correction engine to pass the EDAC Check
Bit 2 through pin 6 of the UT80CRH196KDS.
7TI P0.2 --- Port 0 Pin 2. An input only port pin that is read at location 0Eh
in HWindow 0.
TB ECB11--- EDAC Check Bit 1. Asserting the EDACEN pin will cause the
error detection and correction engine to pass the EDAC Check
Bit 1 through pin 7 of the UT80CRH196KDS.
8TI P0.6 --- Port 0 Pin 6. An input only port pin that is read at location 0Eh
in HWindow 0.
TB ECB01--- EDAC Check Bit 0. Asserting the EDACEN pin will cause the
error detection and correction engine to pass the EDAC Check
Bit 0 through pin 8 of the UT80CRH196KDS.
9TI P0.7 --- Port 0 Pin 7. An input only port pin that is read at location 0Eh
in HWindow 0.
TI EXTINT High External Interrupt. Setting IOC1.1 = 1 enables pin 9 as the
source for the external interrupt EXTINT. A rising edge on this
pin will generate EXTINT (INT07, 200Eh). Assert EXTINT for
at least 2 state times to ensure acknowledgment by the interrupt
controller.
During Power Down mode, asserting EXTINT places the chip
back into normal operation, even if EXTINT is masked.
10 TI P0.5 --- Port 0 Pin 5. An input only port pin that is read at location 0Eh
in HWindow 0.
11 TI P0.4 --- Port 0 Pin 4. An input only port pin that is read at location 0Eh
in HWindow 0.
12 GND VSS --- Digital circuit ground (0V). There are 4 VSS pins, all of which
must be connected and one additional recommended VSS con-
nection.
13 PWR VDD --- Digital supply voltage (+5V). There are 2 VDD pins, both of
which must be connected.
14 GND VSS --- Digital circuit ground (0V). There are 4 VSS pins, all of which
must be connected and one additional recommended VSS con-
nection.
Table 10: 68-lead Flat Pack Pin Descriptions
QFP Pin# I/O Name Active Description
15
15 TI P2.2 --- Port 2 Pin 2. An input only port pin that is written at location
10h of HWindow 0. P2.2 will always generate EXTINT1
(INT13, 203Ah) unless masked by the INT_MASK1 register.
Assert EXTINT1 for at least 2 state times to guarantee acknowl-
edgment by the interrupt controller.
TI EXTINT High External Interrupt. Setting IOC1.1 = 0 enables pin 15 as the
source for the external interrupt EXTINT. A rising edge on this
pin will generate EXTINT (INT07, 200Eh). Assert EXTINT for
at least 2 state times to ensure acknowledgment by the interrupt
controller.
During Power Down mode, asserting EXTINT places the chip
back into normal operation, even if EXTINT is masked.
16 TUBS RESET Low Master Reset. The first external reset signal supplied to the
UT80CRH196KDS must be active for at least 16 state times.
All subsequent RESET assertions need only be active for 1 state
time because the UT80CRH196KDS will continue driving the
RESET signal for an additional 16 state times. See section 1.1.2
for more information on the RESET function of the
UT80CRH196KDS.
17 TI P2.1 --- Port 2 Pin 1. An input only port pin that is read at location 10h
of HWindow 0.
Setting SPCON.3 = 0 enables the P2.1 function of pin 17.
TB RXD --- RXD is a bidirectional serial data port. When operating in Serial
Modes 1, 2, and 3, RXD receives serial data. When using Serial
Mode 0, RXD operates as an input and an open-drain output for
data.
Setting SPCON.3 = 1 enables the RXD function of pin 17.
182TUO P2.0 --- Port 2 Pin 0. An output only port pin that is written at location
10h of HWindow 0.
Setting IOC1.5 = 0 enables the P2.0 function of pin 18.
TUO TXD --- Transmit Serial Data (TXD). When set to Serial Mode 1, 2, or 3,
TXD transmits serial port data. When using Serial Mode 0,
TXD is used as the Serial Clock output.
Setting IOC1.5 = 1 enables the TXD function of pin 18.
TUI ICT Low In-Circuit Test. The UT80CRH196KDS will enter the In-Cir-
cuit Test mode if this pin is held low during the rising edge of
RESET.
Table 10: 68-lead Flat Pack Pin Descriptions
QFP Pin# I/O Name Active Description
16
19 TUQ P1.0 --- Port 1 Pin 0. A quasi-bidirectional port pin that is read and writ-
ten at location 0Fh of HWindow 0.
20 TUQ P1.1 --- Port 1 Pin 1. A quasi-bidirectional port pin that is read and writ-
ten at location 0Fh of HWindow 0.
21 TUQ P1.2 --- Port 1 Pin 2. A quasi-bidirectional port pin that is read and writ-
ten at location 0Fh of HWindow 0.
22 TUQ P1.3 --- Port 1 Pin 3. A quasi-bidirectional port pin that is read and writ-
ten at location 0Fh of HWindow 0.
Setting IOC3.2 = 0 enables the P1.3 function of pin 22.
TUO PWM1 --- Pulse Width Modulator (PWM) Output 1. The output signal
will be a waveform whose duty cycle is programmed by the
PWM1_CONTROL register, and the frequency is selected by
IOC2.2.
Setting IOC3.2 = 1 enables the PWM1 function of pin 22.
23 TUQ P1.4 --- Port 1 Pin 4. A quasi-bidirectional port pin that is read and writ-
ten at location 0Fh of HWindow 0.
Setting IOC3.3 = 0 enables the P1.4 function of pin 23.
TUO PWM2 --- Pulse Width Modulator (PWM) Output 2. The output signal
will be a waveform whose duty cycle is programmed by the
PWM2_CONTROL register, and the frequency is selected by
IOC2.2.
Setting IOC3.3 = 1 enables the PWM2 function of pin 23.
24 TI HSI.0 --- High Speed Input Module, input pin 0. Unless masked, a rising
edge on this input will generate the HSI.0 Pin interrupt (INT04,
2008h). Assert the HSI.0 pin for at least 2 state times to ensure
acknowledgment by the interrupt controller.
Setting IOC0.0 = 1 enables pin 24 as an HSI input, and allows
events on this pin to be loaded into the HSI FIFO.
TI T2RST High Timer 2 Reset. A rising edge on the T2RST pin resets Timer 2.
To enable the T2RST function of pin 24, set IOC0.3 = 1 and
IOC0.5 = 1.
Table 10: 68-lead Flat Pack Pin Descriptions
QFP Pin# I/O Name Active Description
17
25 TI HSI.1 --- High Speed Input Module, input pin 1.
Setting IOC0.2 = 1 enables pin 25 as an HSI input, and allows
events on this pin to be loaded into the HSI FIFO.
TI T2CLK --- Timer 2 Clock.
Setting IOC0.7 = 1 and IOC3.0 = 0 enables pin 25 to function as
the Timer 2 clock source.
26 TO HSO.4 --- High Speed Output Module, output pin 4. This pin can simulta-
neously operate in the HSI and HSO modes of operation. As a
result, this pin acts as an output that the HSI monitors.
Setting IOC1.4 = 1 enables the HSO.4 function of pin 26.
TI HSI.2 --- High Speed Input Module, input pin 2. This pin can simulta-
neously operate in the HSI and HSO modes of operation. As a
result, this pin can monitor events on the HSO.
Setting IOC0.4 = 1 enables pin 26 as an HSI input pin, and
allows events on this pin to be loaded into the HSI FIFO.
27 TO HSO.5 --- High Speed Output Module, output pin 5. This pin can simulta-
neously operate in the HSI and HSO modes of operation. As a
result, this pin acts as an output that the HSI monitors.
Setting IOC1.6 = 1 enables the HSO.5 function of pin 27.
TI HSI.3 --- High Speed Input Module, input pin 3. This pin can simulta-
neously operate in the HSI and HSO modes of operation. As a
result, this pin can monitor events on the HSO.
Setting IOC0.6 = 1 enables pin 27 as an HSI input pin, and
allows events on this pin to be loaded into the HSI FIFO.
28 TDO HSO.0 --- High Speed Output Module, output pin 0. The HSO.0 pin is a
dedicated output for the HSO module.
29 TDO HSO.1 --- High Speed Output Module, output pin 1. The HSO.1 pin is a
dedicated output for the HSO module.
Table 10: 68-lead Flat Pack Pin Descriptions
QFP Pin# I/O Name Active Description
18
30 TUQ P1.5 --- Port 1 Pin 5. A quasi-bidirectional port pin that is read and writ-
ten at location 0Fh of HWindow 0.
Setting WSR.7 = 0 enables the P1.5 function of pin 30.
TUO BREQ Low Bus Request. The BREQ output signal asserts during a HOLD
cycle when the internal bus controller has a pending external
memory cycle.
During a HOLD cycle, BREQ will not be asserted until the
HLDA signal is asserted. Once asserted, BREQ does not deas-
sert until the HOLD signal is released.
Setting WSR.7 = 1 enables the BREQ function of pin 30.
312TUQ P1.6 --- Port 1 Pin 6. A quasi-bidirectional port pin that is read and writ-
ten at location 0Fh of HWindow 0.
Setting WSR.7 = 0 enables the P1.6 function of pin 31.
TUO HLDA Low Bus Hold Acknowledge. The UT80CRH198KD asserts the
HLDA signal as a result of another device activating the HOLD
signal. By asserting this signal, the UT80CRH196KDS is indi-
cating that it has released the bus.
Setting WSR.7 = 1 enables the HLDA function of pin 31.
32 TUQ P1.7 --- Port 1 Pin 7. A quasi-bidirectional port pin that is read and writ-
ten at location 0Fh of HWindow 0.
Setting WSR.7 = 0 enables the P1.7 function of pin 32.
TUI HOLD Low Bus Hold. The HOLD signal is used to request control of the
bus by another DMA device.
Setting WSR.7 = 1 enables the HOLD function of pin 32.
33 TUQ P2.6 --- Port 2 Pin 6. A quasi-bidirectional port pin that is read and writ-
ten at location 10h of HWindow 0.
Setting IOC2.1 = 0 enables the P2.6 function of pin 33.
TUI T2UP-DN --- Timer 2 Up or Down. The T2UP-DN pin will dynamically
change the direction that Timer 2 counts.
T2UP-DN = 1 then Timer 2 counts down.
T2UP-DN = 0 then Timer 2 counts up.
Setting IOC2.1 = 1 enables the T2UP-DN function of pin 33.
When IOC2.1 = 0, Timer 2 will only count up.
Table 10: 68-lead Flat Pack Pin Descriptions
QFP Pin# I/O Name Active Description
19
34 TDO HSO.2 --- High Speed Output Module, output pin 2. The HSO.2 pin is a
dedicated output for the HSO module.
35 TDO HSO.3 --- High Speed Output Module, output pin 3. The HSO.3 pin is a
dedicated output for the HSO module.
36 GND VSS --- Digital circuit ground (0V). There are 4 VSS pins, all of which
must be connected and one additional recommended VSS con-
nection.
37 TI EDACEN Low EDAC Enable. Asserting the EDACEN signal activates the
error detection and correction engine. This causes the
UT80CRH196KDS to include ECB(5:0) as the EDAC check bit
pins in all external memory cycles.
38 TUQ P2.7 --- Port 2 Pin 7. A quasi-bidirectional port pin that is read and writ-
ten at location 10h of HWindow 0.
TUQ T2CAPTURE High Timer 2 Capture. A rising edge on this pin loads the value of
Timer 2 into the T2CAPTURE register, and generates a Timer 2
Capture interrupt (INT11, 2036h). Assert the T2CAPTURE sig-
nal for at least 2 state times to guarantee acknowledgment by the
interrupt controller. Using INT_Mask1.3 controls whether or not
a rising edge causes an interrupt.
39 TDO P2.5 --- Port 2 Pin 5. An output only port pin that is written at location
10h of HWindow 0.
Setting IOC1.0 = 0 enables the P2.5 function of pin 39.
TDO PWM0 --- Pulse Width Modulator (PWM) Output 0. The output signal
will be a waveform whose duty cycle is programmed by the
PWM0_CONTROL register, and the frequency is selected by
IOC2.2.
Setting IOC1.0 = 1 enables the PWM0 function of pin 39.
402TUO WR Low Write. The WR signal indicates that an external write is occur-
ring. Activation of this signal only occurs during external mem-
ory writes.
Setting CCR.2 = 1 enables the WR function of pin 40.
TUO WRL Low Write Low. The WRL signal is activated when writing the low
byte of a 16-bit wide word, and is always asserted for 8-bit wide
memory writes.
Setting CCR.2 = 0 enables the WRL function of pin 40.
Table 10: 68-lead Flat Pack Pin Descriptions
QFP Pin# I/O Name Active Description
20
41 TUO BHE Low Byte High Enable. The assertion of the BHE signal will occur
for all 16-bit word writes, and high byte writes in both 8- and 16-
bit wide bus cycles.
Setting CCR.2 = 1 enables the BHE function of pin 41.
TUO WRH Low Write High. The WRH signal is asserted for high byte writes,
and word writes for 16-bit wide bus cycles. Additionally, WRH
is asserted for all write operations when using an 8-bit wide bus
cycle.
Setting CCR.2 = 0 enables the WRH function of pin 41.
42 TI P2.4 --- Port 2 Pin 4. An input only port pin that is read at location 10h
of HWindow 0.
TI T2RST High Timer 2 Reset. Asserting the T2RST signal will reset Timer 2.
To enable the T2RST function of pin 42, set IOC0.3 = 1 and
IOC0.5 = 0.
43 TI READY High READY input. The READY signal is used to lengthen memory
cycles by inserting “wait states” for interfacing to slow peripher-
als. When the READY signal is high, no “wait states” are gener-
ated, and the CPU operation continues in a normal fashion. If
READY is low during the falling edge of CLKOUT, the mem-
ory controller inserts “wait states” into the memory cycle. “Wait
state” generation will continue until a falling edge of CLKOUT
detects READY as logically high, or until the number of “wait
states” is equal to the number programmed into CCR.4 and
CCR.5.
Note: The READY signal is only used for external memory
accesses, and is functional during the CCR fetch.
44 TI P2.3 --- Port 2 Pin 3. An input only port pin that is read at location 10h
of HWindow 0.
TI T2CLK --- Timer 2 Clock input. Setting IOC0.7 = 0 and IOC3.0 = 0
enables this pin as the external clock source for Timer 2.
IOC0.7: IOC3.0: Timer 2 Clock Source:
X 1 Internal Clock Source
0 0 P2.3 External Clock Source
1 0 HSI.1 External Clock Source
45 TUB AD15 --- Bit 15 of the Address/Data bus. This pin is a dedicated address
pin when operating with 8-bit wide bus cycles. For 16-bit wide
bus cycles, this pin is used as multiplexed address and data.
Table 10: 68-lead Flat Pack Pin Descriptions
QFP Pin# I/O Name Active Description
21
46 TUB AD14 --- Bit 14 of the Address/Data bus. This pin is a dedicated address
pin when operating with 8-bit wide bus cycles. For 16-bit wide
bus cycles, this pin is used as multiplexed address and data.
47 TUB AD13 --- Bit 13 of the Address/Data bus. This pin is a dedicated address
pin when operating with 8-bit wide bus cycles. For 16-bit wide
bus cycles, this pin is used as multiplexed address and data.
48 TUB AD12 --- Bit 12 of the Address/Data bus. This pin is a dedicated address
pin when operating with 8-bit wide bus cycles. For 16-bit wide
bus cycles, this pin is used as multiplexed address and data.
49 TUB AD11 --- Bit 11 of the Address/Data bus. This pin is a dedicated address
pin when operating with 8-bit wide bus cycles. For 16-bit wide
bus cycles, this pin is used as multiplexed address and data.
50 TUB AD10 --- Bit 10 of the Address/Data bus. This pin is a dedicated address
pin when operating with 8-bit wide bus cycles. For 16-bit wide
bus cycles, this pin is used as multiplexed address and data.
51 TUB AD9 --- Bit 9 of the Address/Data bus. This pin is a dedicated address
pin when operating with 8-bit wide bus cycles. For 16-bit wide
bus cycles, this pin is used as multiplexed address and data.
52 TUB AD8 --- Bit 8 of the Address/Data bus. This pin is a dedicated address
pin when operating with 8-bit wide bus cycles. For 16-bit wide
bus cycles, this pin is used as multiplexed address and data.
53 TUB AD7 --- Bit 7 of the Address/Data bus. This pin is used as multiplexed
address and data for both 8- and 16-bit wide bus cycles.
54 TUB AD6 --- Bit 6 of the Address/Data bus. This pin is used as multiplexed
address and data for both 8- and 16-bit wide bus cycles.
55 TUB AD5 --- Bit 5 of the Address/Data bus. This pin is used as multiplexed
address and data for both 8- and 16-bit wide bus cycles.
56 TUB AD4 --- Bit 4 of the Address/Data bus. This pin is used as multiplexed
address and data for both 8- and 16-bit wide bus cycles.
57 TUB AD3 --- Bit 3 of the Address/Data bus. This pin is used as multiplexed
address and data for both 8- and 16-bit wide bus cycles.
58 TUB AD2 --- Bit 2 of the Address/Data bus. This pin is used as multiplexed
address and data for both 8- and 16-bit wide bus cycles.
59 TUB AD1 --- Bit 1 of the Address/Data bus. This pin is used as multiplexed
address and data for both 8- and 16-bit wide bus cycles.
60 TUB AD0 --- Bit 0 of the Address/Data bus. This pin is used as multiplexed
address and data for both 8- and 16-bit wide bus cycles.
Table 10: 68-lead Flat Pack Pin Descriptions
QFP Pin# I/O Name Active Description
22
Notes:
1. These pins should be pulled high or low when using EDAC (i.e. EDACEN = 0) to prevent the voltages on these pins from floating to the switching threshold of
the input buffers during long read cycles.
2. These pins must be high on the rising edge of RESET in order to avoid entering any test modes.
3. This pin is a recommended VSS connection. The remaining 4 VSS pins are required to be tied to the circuit card ground plane.
612TUO RD Low Read. The RD signal is an output to external memory that is
only asserted during external memory reads.
622TUO ALE High Address Latch Enable. The ALE signal is an output to external
memory that is only asserted during external memory accesses.
ALE is used to specify that valid address information is avail-
able on the address/data bus, and signals the start of a bus cycle.
ALE is used by an external latch to demultiplex the address from
the address/data bus. Setting CCR.3 = 1 enables the ALE func-
tion of pin 62.
TUO ADV Low Address Valid. The ADV signal is an output to external mem-
ory that is only asserted during external memory accesses. ADV
is driven high to specify that valid address information is avail-
able on the address/data bus. The ADV signal is held low during
the data transfer portion of the bus cycle, and is driven high
when the bus cycle completes. ADV is used by an external latch
to demultiplex the address from the address/data bus. Setting
CCR.3 = 0 enables the ADV function of pin 62.
63 TDO INST High Instruction Fetch. The INST signal indicates the type of external
memory cycle being performed. The INST signal will be high
during instruction fetches, and will be low for data fetches.
Note: CCB bytes and Interrupt vectors are considered data.
64 TI BUSWIDTH --- Bus Width. The BUSWIDTH pin dynamically modifies the
width of bus cycles. When a high logic value is supplied, the
bus width will be set to 16-bits wide. When a low logic level is
supplied, the bus width will be set to 8-bits wide.
Setting CCR.1 = 1 enables the BUSWIDTH pin. Setting
CCR.1 = 0 disables the BUSWIDTH pin. As a result, the
UT80CRH196KDS will only perform 8-bit wide bus cycles.
65 TUO CLKOUT --- Clock Output. The CLKOUT signal is the output of the internal
clock. This signal has a 50% duty cycle, and runs at 1/2 the fre-
quency of the system clock input to XTAL1. Setting IOC3.1 = 0
will enable the CLKOUT output signal.
66 GND VSS3--- Digital circuit ground (0V). Recommended connection for sig-
nal integrity improvement. There are 4 other VSS pins, all of
which must be connected.
67 CI XTAL1 --- External oscillator or clock input to the UT80CRH196KDS.
The XTAL1 input is fed to the on-chip clock generator.
68 GND VSS --- Digital circuit ground (0V). There are 4 VSS pins, all of which
must be connected and one additional recomended VSS connec-
tion.
Table 10: 68-lead Flat Pack Pin Descriptions
QFP Pin# I/O Name Active Description
23
2.0 RADIATION HARDNESS
The UT80CRH196KDS incorporates special design and layout
features and is built on UTMC’s Commercial RadHardTM
silicon. The Commercial RadHardTM
silicon is fabricated using
a minimally invasive process module, developed by UTMC, that
enhances the total dose radiation hardness of the field and gate
oxides while maintaining current density and reliability. In
addition, for both greater transient radiation-hardness and latch-
up immunity, the UT80CRH196KDS is built on epitaxial
substrate wafers.
RADIATION HARDNESS DESIGN SPECIFICATIONS
Notes:
1. Worst case temperature TA = 25oC for Single Event Upset and 100oC for Single Event Latchup.
2. Adams 90% worst case environment (geosynchronous).
3. Total effective error rate based on the combined error rates of both the register and SRAM elements in the device
WEIBULL PARAMETERS FOR ALL 1482 REGISTER ELEMENTS
WEIBULL PARAMETERS FOR ALL 8192 SRAM ELEMENTS
3.0 ABSOLUTE MAXIMUM RATINGS 1 (Referenced to VSS)
Notes:
1. Stresses outside the listed absolute maximum ratings may cause permanent damage to the device. This is a stress rating only, and functional operation of the device
at these or any other conditions beyond limits indicated in the operational sections of this specification is not recommended. Exposure to absolute maximum rating
conditions for extended periods may affect device reliability.
2. These ratings are provided as design guidelines. They are not guaranteed by test or characterization.
3. Test per MIL-STD-883, Method 1012.
Total Dose 3.0E5 rads(Si)
Onset LET Threshold 25 MeV-cm2/mg
Neutron Fluence 1.0E14 n/cm2
Saturated Cross-Section (1Kx8) 6.0E-7 cm2/bit
Single Event Upset13.5048E-6 errors/device day2, 3
Single Event Latchup1LET > 128 MeV-cm2/mg
SHAPE
PARAMETER WIDTH
PARAMETER SATURATED
CROSS-SECTION ONSET
LET DEVICE
DEPTH FUNNEL
DEPTH
1.3 18.5 1.5E-7cm2/bit 48MeV-cm2/mg 0.8µm1.45µm
SHAPE
PARAMETER WIDTH
PARAMETER SATURATED
CROSS-SECTION ONSET
LET DEVICE
DEPTH FUNNEL
DEPTH
4150 6.0E-7cm2/bit 25MeV-cm2/mg 0.5µm0.5µm
SYMBOL PARAMETER LIMITS UNITS
VDD DC Supply Voltage -0.3 to 6.0 V
VI/O 2Voltage on Any Pin -0.3 to VDD+0.3V V
TSTG Storage Temperature -65 to +150 °C
TJMaximum Junction Temperature 175 °C
ΘJC Thermal Resistance, Junction-to-Case 32°C/W
II2DC Input Current ±10 mA
24
4.0 DC ELECTRICAL CHARACTERISTICS (Pre/Post-Radiation)*
(VDD = 5.0V ±10%) (TC = -55°C to +125°C for "C" screening and -40°C to +125°C for "W" screening)
SYMBOL PARAMETER CONDITION MINIMUM MAXIMUM UNIT
VIL Low-level Input Voltage
(except XTAL1, RESET)0.8 V
VIH High-level Input Voltage
(except XTAL1, RESET)2.2 V
VIH1 High-level Input Voltage
(XTAL1) .7VDD V
VIL1 Low-level Input Voltage
(XTAL1) .3VDD V
VT+ Positive Going Threshold
RESET .5VDD .7VDD V
VT- Negative Going Threshold
RESET .3VDD .5VDD V
VHTypical Range of Hysteresis6
RESET
.6 V
VOL Low-level Output Voltage
(CMOS load) IOL = 100µA60.25 V
(TTL load) IOL = 4.0mA
IOL = 8.0mA5
0.4
0.4 V
VOH High-level Output Voltage8
(CMOS load)
(Standard outputs) (TTL load) IOH = -100µA6
IOH = -4.0mA
IOH = -8.0mA5
VDD-.25
2.4
2.4
V
V
V
IOH1 High-level Output Current1
(Open drain outputs with pullups) VOH = VSS (see Note 6) -225 -20 µA
IIH Logical 1 Input Current2
(Test mode entry avoidance)VIN = VIH -225 -20 µA
ILI I/O Leakage Current, standard
inputs/outputs in Z state VIN = VSS or VDD Outputs in Z
VIN = VSS or VDD Inputs in Z
-10
-1 +10
+1 µA
µA
ILI1 I/O Leakage Current, with pullups3VIN = VSS -225 -20 µA
ILI2 I/O Leakage Current, with
pulldowns4VIN = VDD 20 225 µA
CIO Pin Capacitance6@ 1MHZ, 25°C15 pF
ΑIDD Active Power Supply Current Clk@20MHz, typical program
flow 130 mA
QIDD Quiescent Power Supply Current Unloaded TMIN tο +25°C
Outputs +125°C
No Clock +25°C post-100krad
+25°C post-300krad
20
1000
1000
14,000
µA
µA
µA
µA
IDDPD Power Supply Current in Power
Down No Active I/O, Clk@20MHz
post-100krad
No Active I/O, Clk@20MHz
post-300krad
6
19
mA
mA
25
Notes:
* Post-radiation performance guaranteed at 25°C per MIL-STD-883.
1. Open-drain outputs with pullups include Port 1, P2.6 and P2.7, and RESET.
2. Test modes are entered at the RESET rising edge by applying VIL to one or more of the following pins: TXD, RD, WR, HLDA. To avoid entering a test mode,
ensure that these pins remain above VIH at the rising edge of RESET.
3. Inputs/outputs with pullup resistors include: RESET, Port 1, P2.0, P2.6, P2.7, WR, BHE, AD0-15, RD, ALE, CLKOUT.
4. Inputs/outputs will pulldown resistors include: NMI, HS0.0-HS0.3, P2.5, INST.
5. Applies to pins RESET, BHE, RD, C LKOUT.
6. Tested only at initial qualification and after any design or process changes which may affect this characteristic.
7. Not more than one output may be shorted at a time for maximum duration of one second.
8. For standard outputs not covered by IOH1 spec.
IDDIDLE Power Supply Current in Idle Mode No Active I/O, Clk@20MHZ
+25oC, post -300Krad
55
62 mA
IDDRESET Power Supply Current in Reset CLK @20 MHz, RESET < VIL 76 mA
IOS Short Circuit output current (except
for pins listed in Note 5)6,7 VDD = 5.5V -100 100 mA
IOS1 Short Circuit output current5,6,7 VDD = 5.5V -200 200 mA
26
5.0 AC CHARACTERISTICS READ CYCLE (Post-Radiation)*
(VDD = 5.0V ±10%) (TC = -55°C to +125°C for "C" screening and -40°C to +125°C for "W" screening)
SYMBOL PARAMETER MINIMUM MAXIMUM UNIT
tAVYV5Address VALID to READY setup 2TOSC - 30 ns
tYLYH5Non-READY time No upper limit ns
tCLYX1,5 READY hold after CLKOUT low 02TOSC - 20 ns
tLLYX1,5 READY hold after ALE low TOSC 3TOSC - 20 ns
tAVGV5Address valid to BUSWIDTH setup 2TOSC - 30 ns
tCLGX5BUSWIDTH hold after CLKOUT low 0 ns
tAVDV2,5 Address valid to input data valid 3TOSC - 29 ns
tRLDV2RD Active to input data valid 5 (see Note 5) TOSC - 26 ns
tCLDV5CLKOUT low to input data valid 5TOSC - 26 ns
tRHDZ5End of RD to input data float 0TOSC -10 ns
tRXDX5Data hold after RD inactive 0TOSC -10 ns
fOSC5Frequency on XTAL1 1 (see Note 7) 20 (see Note 6) Mhz
TOSC5XTAL1 period (1/fOSC)50 (see Note 6) 1000 (see Note 7) ns
tXHCH XTAL1 high to CLKOUT high or low 0+25 ns
tCLCL6CLKOUT cycle time 2TOSC Typical ns
tCHCL5CLKOUT high period TOSC - 10 TOSC +10 ns
tCLLH CLKOUT falling edge to ALE rising -5 +15 ns
tLLCH5ALE falling edge to CLKOUT rising -10 +10 ns
tLHLH2, 6 ALE cycle time 4TOSC Typical ns
tLHLL5ALE high period TOSC - 10 TOSC +15 ns
tAVLL5Address and ADV_RD_WR setup to ALE falling
edge TOSC - 15 ns
tLLAX5Address and ADV_RD_WR hold after ALE
falling edge TOSC - 20 TOSC +5 ns
tLLRL ALE falling edge to RD falling edge TOSC - 5 TOSC +10 ns
tRLCL RD low to CLKOUT falling edge -5 +10 ns
tRLRH2RD low period TOSC - 5 ns
tRHLH3,5 RD rising edge to ALE rising edge TOSC-10 TOSC +10 ns
tRLAZ5RD low to address float -5 +5 ns
27
Note:
* Post-radiation performance guaranteed at 25°C per MIL-STD-883 Method 1019 at 1.0E5 rads(Si).
1. If max exceeded, additional wait state occurs.
2. If wait states are used, add 2 TOSC *N, where N = number of wait states.
3. Assuming back-to-back bus cycles.
4. 8-bit only
5. Tested only at initial qualification, and after any design or process changes which may affect this characteristic.
6. These specs are verified using functional vectors (strobed) only.
7. Low speed tests performed at 5MHz. 1MHz operation is guaranteed by design.
tLLWL5ALE falling edge to WR falling edge TOSC - 10 TOSC +10 ns
tCLWL CLKOUT low to WR falling edge -5 +10 ns
tQVWH2Data stable to WR rising edge TOSC - 10 TOSC +10 ns
tCHWH5CLKOUT high to WR rising edge -10 +15 ns
tWLWH2,5 WR low period TOSC - 10 ns
tWHQX5Data hold after WR rising edge TOSC - 10 TOSC +10 ns
tWHLH3,5 WR rising edge to ALE rising edge TOSC - 10 TOSC +10 ns
tWHBX5BHE, INST after WR rising edge TOSC - 10 TOSC +10 ns
tWHAX4,5 AD8-15 HOLD after WR rising TOSC - 25 ns
tRHBX5BHE, INST after RD rising edge TOSC - 10 TOSC +10 ns
tRHAX4,5 AD8-15 HOLD after RD rising TOSC - 25 ns
tAVENV5Address valid to EDACEN valid 2TOSC -30 ns
tLHENX5EDACEN hold after ALE high 0ns
tAVEV2,5 Address valid to EDAC input valid 3TOSC -29 ns
tRXEX5EDAC hold after RD inactive 0TOSC -10 ns
tEVWH2,5 EDAC output stable to WR rising TOSC -10 TOSC +10 ns
tWHEX5EDAC output hold after WR rising TOSC -10 TOSC +10 ns
28
XTAL1
CLKOUT
READ
BUS
WRITE
BUS
BHE, INST
AD8-15
tLLCH
tCLCL
tXHCH tCHCL
tRLCL
ALE
tLHLH
tLHLL tLLRL tRHLH
tRLRH
tRLDV
tLLAX
tAVLL
tRLAZ
tRHDZ
TOSC
Figure 4. System Bus Timings
ADDRESS OUT DATA
tAVDV
tLLWL tWLWH
tWHLH
tWHQX
tQVWH
ADDRESS OUT DATA OUT ADDRESS
ADDRESS OUT
VALID
tWHBX, tRHBX
tCLDV
tRXDX
tCLWL
tCLLH
tCHWH
tWHAX, tRHAX
ECB(4:0)
READ CYCLE
ECB(4:0)
WRITE CYCLE
tAVEV VALID
tRXEX
VALID
tWHEX
tEVWH
ECB5/ADV_RD_WR
READ CYCLE
ECB5/ADV_RD_WR
WRITE CYCLE
tAVLL tLLAX
tAVEV
ECB5 VALID
tRXEX
ECB5 VALID
tAVLL tLLAX tEVWH tWHEX
29
XTAL1
CLKOUT
ALE
READY
READ
BUS
WRITE
BUS
ADDRESS OUT
ADDRESS DATA OUT ADDRESS
DATA
tRLRH + 2TOSC
tWLWH +2TOSC
TOSC
tCHCL
tRLDV+ 2TOSC
tAVYV
tQVWH + 2TOSC
tAVDV+ 2TOSC
tXHCH
tCLCL
tLHLH + 2TOSC
tCLLH tLLYX
max
tCLYX
max
tLLYX
min
tCLYX
min
tYLYH
Figure 5. READY Timing (One Wait State)
30
Figure 6. BUSWIDTH and EDACEN Timings
CLKOUT
ALE
BUSWIDTH
BUS
tCLGX
XTAL1
VALID
tAVGV
ADDRESS OUT DATA
EDACEN
tAVENV
VALID
tLHENX
31
6.0 XTAL1 CLOCK DRIVE TIMING CHARACTERISTICS
Note:
1. Tested only at initial qualification, and after any design or process changes which may affect this characteristic.
2. Supplied as a design limit, but not guaranteed or tested.
Figure 7. External Clock Drive Timing Waveforms
SYMBOL PARAMETER MINIMUM MAXIMUM UNIT
fOSC Oscillator Frequency 1(note 1) 20 MHz
TOSC Oscillator Period 50 1000(note 1)ns
tOSCH High Time 17(note 1)ns
tOSCL Low Time 17(note 1) ns
tOSCR Rise Time 10(note 2) ns
tOSCF Fall Time 10(note 2)ns
tOSCH
TOSC
tOSCF
tOSCR
0.7 VDD 0.7 VDD
0.3VDD
0.3VDD
tOSCL
0.7 VDD
32
Note:
1.Tested only at initial qualification, and after any design or process changes which may affect this characteristic.
7.0 HOLD/HLDA Timings
Note:
1.Tested only at initial qualification, and after any design or process changes which may affect this characteristic.
Table 11. DC Specifications in Hold1
DESCRIPTION MIN MAX CONDITIONS
Pullups on ADV, RD, WR, WRL, BHE, ALE 24.4K275K VDD =5.5V, VIN = VSS
Pulldown on INST 24.4K275K VDD =5.5V, VIN = VDD
SYMBOL PARAMETER MINIMUM MAXIMUM UNIT
tHVCH1HOLD Setup 25 ns
tCLHAL1CLKOUT low to HLDA low -15 15 ns
tCLBRL1CLKOUT low to BREQ low -15 15 ns
tHALAZ1HLDA low to address float 10 ns
tHALBZ1HLDA low to BHE, INST, RD, WR
driven weakly 15 ns
tCLHAH1CLKOUT low to HLDA high -15 15 ns
tCLBRH
1CLKOUT low to BREQ high -15 15 ns
tHAHAX1HLDA high to address no longer float -15 ns
tHAHBV1HLDA high to BHE, INST, RD, WR valid -10 ns
33
CLKOUT
HOLD
HLDA
BREQ
BUS
ALE/ADV
BHE, INST
RD, WR
tHVCH tHVCH
tCLHAL tCLHAH
tCLBRL tCLBRH
tHAHAX
tHALAZ
tHALBZ tHAHBV
Weakly Driven Inactive
Weakly Driven High
Figure 8. DC Specifications In Hold
34
UT80CRH196KDS
XTAL1
External Clock
Input
Figure 9. External Clock Connections
VDD
0.0V 1.4V 1.4V
TEST POINTS
AC Testing inputs are driven at VDD for a Logic “1” and 0.0V for a Logic “0”. Timing measure-
ments are made at 1.4V.
Figure 10. AC Testing Input, Output Waveforms
VLOAD
For timing purposes a port pin is no longer floating when it changes to a voltage outside the ref-
erence points shown and begins to float when it changes to a voltage inside the reference points
shown. IOL = 4mA, IOH = -4mA.
VOL + 0.5V
VOH - 0.5V
VOL + 0.5V
VOH - 0.5V
TIMING REFERENCE
POINTS
Figure 11. Float Waveforms
35
Table 12. Serial Port Timing
SYMBOL PARAMETER MINIMUM MAXIMUM UNIT
tXLXL2Serial port clock period (BRR > 8002H) 6 TOSC typical ns
tXLXH1Serial port clock falling edge to rising edge
(BRR > 8002H) 4 TOSC -50 4 TOSC +50 ns
tXLXL2Serial port clock period (BRR = 8001H) 4 TOSC typical ns
tXLXH1Serial port clock falling edge to rising edge
(BRR = 8001H) 2 TOSC -50 2 TOSC +50 ns
tQVXH
1Output data valid to clock rising edge 2 TOSC -50 ns
tXHQX
1Output data hold after clock rising edge 2 TOSC -50 ns
tXHQV
1Next output data valid after clock rising edge 2 TOSC +50 ns
tDVXH
1Input data setup to clock rising edge TOSC +50 ns
tXHDX
1Input data hold after clock rising edge 0ns
tXHQZ1Last clock rising to output float 2 TOSC -10 2 TOSC +10 ns
TXD
RXD (OUT)
RXD (IN)
0 1 2 3 4 5 6 7
TXLXL
tQVXH tXHQV tXHQX
tDVXH
tXHDX
tXLXH
tXHQZ
Figure 12. Serial Port Waveform - Shift Register Mode
0 1 2 3 54
6
76
Note:
1.Tested only at initial qualification, and after any design or process changes which may affect this characteristic.
2. These specs are verified using functional vectors (strobed) only.
36
APPENDIX A
Difference Between Industry Standard and UT80CRH196KDS
1.0 DIFFERENCES TO INDUSTRY
STANDARD 80C196KD
1.1 Analog to Digital Converter
The Analog to Digital Converter will not be implemented in the
UT80CRH196KDS.
1.3 Clocking
The XTAL2 output is not used and the UT80CRH196KDS
expects the input on the XTAL 1 to be a valid digital clock
signal. The clock should be stable before reset is removed or
Power Down mode is exited. In Power Down mode, a small
number of gates will be clocked by the XTAL1 input. The
UT80CRH196KDS XTAL2 has been replaced with a VSS pin.
1.4 CCB Read after Reset
The CCB fetch after Reset will be a normal fetch as if the chosen
bus width is selectable based on the BUSWIDTH input.
Systems with an 8-bit wide interface should tie BUSWIDTH to
ground. Systems that use BUSWIDTH should perform a normal
decode based on the memory configuration of the system. The
Industry Standard 80C196KD treats the CCB fetch as an 8-bit
fetch (driving the upper 8-bits with address 20H) regardless of
the state of BUSWIDTH.
1.5 Internal Program Memory
The UT80CRH196KDS does not have internal program
memory, and pin 2 (EA) will be ignored for choosing between
internal and external program reads. The user may tie this pin
to ground for compatibility reasons, unless EDAC is enabled.
1.6 Ports 3 and 4
Since the UT80CRH196KDS will not have internal program
memory, Ports 3 and 4 will always be used as the multiplexed
Address and Data bus. Therefore, these ports will not be
configured as I/O ports, and the bidirectional port function of
these pins will not be implemented. The pins will only be
configured as Address and bidirectional data pins.
1.7 Built in EDAC
The UT80CRH196KDS incorporates a built in Error Detection
and Correction circuit for external memory reads and writes.
The EDAC can be controlled from an external pin. The external
pin (Pin 37) can be used to enable or disable this feature
interactively. Therefore, different regions of external memory
can be assigned to have EDAC as necessary. Additionally, the
EDAC check bits will be passed through Port 0, which varies
from the industry standard version where Port 0 is an input only
port. You can control the interrupt behavior of the EDAC engine
by setting bits 6 and 5 of the EDAC Control and Status Register
(EDAC_CS). Additionally, reading bit 4 of the EDAC_CS
allows you to determine if a double bit error occurred, and
reading bits 3 through 0 of the EDAC_CS Register tells you
how many single bit errors have been corrected. The EDAC_CS
Register is located at location 15h of HWindow 1.
1.8 Instruction Queue
The instruction queue is eight bytes deep instead of four. The
instruction queue also interfaces to the CPU through a 16-bit
bus. This configuration will speed up the operation of the
UT80CRH196KDS.
1.9 WDT and Prescalar
The WDT can now be disabled through the software. The
disable feature should allow the user flexibility in using the
Watch Dog Timer. The WDT also now has a prescalar which
can slow down the counter by a factor of 20 to 27. The prescalar
will give the user extra time between clears of the WDT. The
WDT prescaler (WDT_SCALE) is located at location 0Dh of
HWindow 1.
1.10 Interrupt Priority Levels
An additional level of priority encoding is available to the user.
Every standard interrupt can be programed to a higher level of
priority. All interrupts in the higher priority will maintain their
relative priority, but low priority interrupts can then be
programmed for a higher interrupt priority if necessary. The
interrupt priority register is 16-bits wide, and maps to the
standard interrupts in the same fashion as the INT_MASK and
INT_MASK1 registers. The high byte of the Interrupt Priority
Register (IN_PRI(hi)) is located at 0Bh of HWindow 1, and the
low byte (INT_PRI(lo)) is located at 0Ah of HWindow 1.
1.11 Faster Multiply and Divide
The multiplier and divider have been optimized to perform their
operations in fewer state times than in the current version.
1.12 Instructions State Time Reduction
The CPU has been streamlined for faster execution where
possible. Examples include 1 state reduction for WORD
immediate instructions, 1 state reductions for long indexed
instructions, and state reductions for the BMOV instructions.
1.13 STACK_PNTR implemented as Special Function
Register
The STACK_PNTR has been implemented as a true Special
Function Register instead of in the RAM to allow for quicker
pushes and pops. If the stack is not used, the SFR can be used
for general purpose data storage.
1.14 Timer3
An additional 16-bit timer/counter has been implemented as a
general purpose timer that can be used if Timer1 and Timer 2
are being dedicated to other functional uses. The current value
of Timer3 can be found in locations 0Fh (high byte), and 0Eh
(low byte) of HWindow 1.
37
1.15 Input/Output Pullup/Pulldown Currents
Leakage currents may not meet the industry standard specs due
to differently sized weak pullups/pulldowns, during Quasi-
Bidirectional and reset/powerdown modes. Refer to specs for
ILI1
and ILI2.
1.16 Power-down exit
Pin 37 will not be used to exit power-down mode. Since a digital
clock is supplied, no connection between this Vpp pin and the
power-down circuitry exists.
1.17 Test Mode Entry
Test mode entry will be via four pins: WR, RD, ALE and HLDA
instead of PWM0.
1.18 Power-on Reset
The UT80CRH196KDS will not guarantee the 16-state "pulse
stretching" function of a Reset_n pulse applied at power-up. The
user must hold Reset_n low until the power and clocks stabilize
plus 16-state times, or provide a high to low transition after the
power and clocks have stabilized.
1.19 Pullup/Pulldown states
The INST pin will be driven to a weak low during Reset. The
ALE signal will be driven to a weak high during Bus Hold.
1.20 Modifying the INT_PEND registers
Two operand rd-modify-wr instructions should be used to
modify the INT_PEND registers. Three operand rd-modify-wr
instructions may lose an incoming interrupt.
1.21 Serial Port Synchronous Mode
The last clock rising edge to output float time (TXHQZ) is made
consistent with the output data hold (TXHQX) time of 2 TOSC +/
-50nsec. This is longer than the industry standard of 1 TOSC max.
1.22 Industry Standard Register Indirect with Auto Incre-
ment
The industry standard increments the auto-incremented regis-
ter after determining the external address instead of at the end
of the instruction completion. The UT80CRH196KDS per-
forms the auto-increment function at the end of the instruction
processing. Please reference the example below that shows the
processing difference between the UT80CRH196KDS and the
industry standard:
ST R0, [R0]+
assume R0 holds the value 1000h before the instruction is exe-
cuted.
1.23 AC Timing Differences
There are some AC timing differences between the
UT80CRH196KDS and the industry standard 80C196KD.
Most changes resulted in loosened timing specifications. How-
ever, the tRHDZ and tRXDX timing specifications were tight-
ened by 5ns. If you have been designing to the industry
standard timing specifications, it is important to recognize
these two shortened timing specifications.
NOTE: Please visit the UTMC website at www.utmc.com to
obtain the latest data sheet updates, application notes, software
examples, advisories and erratas for the UT80CRH196KDS.
1.24 T2UP-DN Input Signal
Port 2.6 has an alternate function of T2UP-DN enabled by
IOC2.1. The industry standard device appears to allow writes
into Port 2.6 to directly affect the pin state when in the T2UP-
DN mode. (This would allow software control of the T2 direc-
tion, but requires ensuring a one (QBD pullup) is written to
Port 2.6 if the pin is driven externally). The
UT80CRH196KDS device is designed to disable the Port 2.6
output when T2UP-DN is enabled. This protects the P2.6/
T2UP-DN pin from contention with an externally driven sig-
nal, independent of the value written into Port 2.
1.25 NEG 8000h Instruction Operation
The UT80CRH196KDS and the industry standard 80C196KD
set the N-Flag differently when executing the NEG 8000h
instruction. NEG represents the MCS-96 opcode to negate a
defined operand (8000h). When the UT80CRH196KDS exe-
cutes the NEG 8000h instruction, the result becomes 8000h
with both the N-Flag and the V-Flag set. The industry standard
80C196KD, however, executes the NEG 8000h instruction
with a result of 8000h and only the V-Flag set.
1.26 Reserved Opcode EEH
The industry standard 80C196KD using the MCS-96 ISA
declares the opcode EEH as a reserved opcode and does not
guarantee the generation of the Unimplemented Opcode Inter-
rupt. The UT80CRH196KDS, on the other hand, generates the
Unimplemented Opcode Interrupt when the EEH opcode is
executed.
PROCESSING FLOW FOR THE ST R0, [R0]+
INSTRUCTION
UT80CRH196KDS Industry Standard
Address = [R0]; 1000h Address = [R0]; 1000h
R0 ---> Address R0 = R0+1; 1001h
R0 = R0+1; 1001h R0 ---> Address
* The contents in address
1000h are 1000h * The contents in address
1000h are 1001h
PROCESSING FLOW FOR THE ST R0, [R0]+
INSTRUCTION
UT80CRH196KDS Industry Standard
38
1.27 Advanced Read/Write Signal (ADV_RD_WR)
The UT80CRH196KDS provides an early indication of an
external memory cycle direction being a read or write. This
signal is output on pin 2. See Table 10 and Figure 4 for
description of operation.
1.28 Byte-Wide Reads of the HSI_Time SFR
In order to ensure that the next HSI event is loaded from the
FIFO into the HSI holding register, the HSI_TIME special
function register must be read as a 16-bit word. Byte-wide
reads of the HSI_TIME register will not result in successful
loading of the HSI holding register.
1.29 HOLD Must Be Synchronized with CLKOUT
The DMA arbiter must synchronize the HOLD signal with the
CLKOUT on the UT80CRH196KDS. The timing diagram in
Figure 8 eludes to the synchronicity of the HOLD signal, but
does not clearly identify the outcome if the HOLD signal does
not satisfy the timing parameter tHVCH. If the HOLD setup
time is violated on the industry standard 80CRH196KDS, it
will require one additional CLKOUT cycle before it recog-
nizes the state change of HOLD. Violating the HOLD setup
time on the UT80CRH196KDS will result in a metastable
condition and the UT80CRG196KDS’s reaction is undefined.
39
8.0 PACKAGE
Notes:
1. All package finishes are per MIL-PRF-38535.
2. Letter designations are for cross-reference to MIL-STD-1835.
3. All leads increase max. limit by 0.003 measured at the
center of the flat, when lead finish A (solder) is applied.
4. ID mark: Configuration is optional.
5. Lettering is not subject to marking criteria.
6. Total weight is approx. 8.0 grams.
7. All dimensions are in inches.
Figure 14. 68-lead Quad Flatpack
40
ORDERING INFORMATION
UT80CRH196KDS 16-Bit Microcontroller: SMD
Lead Finish:
(A) = Solder
(C) =Gold
(X) =Optional
Case Outline:
(X) =68-lead top brazed flatpack
Class Designator:
(Q) =Class Q
(V) =Class V
Device Type
(01) = 20 Mhz, 16-bit microcontroller (-55
oC to +125oC)
(02) = 20 Mhz, 16-bit microcontroller, Extended Industrial Temp (-40oC to +125oC)
Drawing Number: 02523
Total Dose:
(R) =1E5 rads(Si)
(F) =3E5 rads(Si)
Federal Stock Class Designator: No options
5962 * 02523 ** * * *
Notes:
1. Lead finish (A, C, or X) must be specified.
2. If an “X” is specified when ordering, part number will match the lead finish and will be either “A” (solder) or “C” (gold).
3. Total dose radiation must be specified when ordering. QML V is not available without radiation testing.
41
UT80CRH196KDS Microcontroller
UT80CRH196KDS - * * *
Notes:
1. Lead finish (A,C, or X) must be specified.
2. If an “X” is specified when ordering, then the part number will match the lead finish and will be either “A” (solder) or “C” (gold).
3. Military Temperature Range flow per UTMC Manufacturing Flows Document. Devices are tested -55C, room temp, and 125C. Radiation is neither
tested nor guaranteed.
4. Prototype flow per UTMC Manufacturing Flows Document Tested at 25C only. Lead finish is gold only. Radiation is neither tested nor guaranteed.
5. Extended Industrial Temperature Range Flow per UTMC Manufacturing Flows Document. Devices are tested at -40oC, room temp, and +125oC.
Radiation is neither tested nor guaranteed.
Lead Finish: (Notes 1, 2)
(A) = Solder
(C) = Gold
(X) = Optional
Screening:(Notes 3, 4, 5)
(C) = Mil Temp
(P) = Prototype
(W) = Extended Industrial Temp (-40oC to +125 oC)
Package Type:
(W) = 68-lead top brazed Flatpack
UTMC Core Part Number
42
Notes
43
Notes