Enhanced Configuration (EPC) Devices Datasheet
2016.05.04
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Supported Devices
Table 1: Altera EPC Devices
Device Memory Size (bits) On-Chip
Decompres‐
sion Support
ISP Support Cascading
Support Reprogram‐
mable
Recommend
ed
Operating Voltage
(V)
EPC4 4,194,304 Yes Yes No Yes 3.3
EPC8 8,388,608 Yes Yes No Yes 3.3
EPC16 16,777,216 Yes Yes No Yes 3.3
Features
EPC devices offer the following features:
Single-chip configuration solution for Altera® ACEX® 1K, APEX® 20K (including APEX 20K, APEX
20KC, and APEX 20KE), APEX II, Arria® GX, Cyclone®, Cyclone II, FLEX® 10K (including FLEX
10KE and FLEX 10KA), Mercury®, Stratix® II, and Stratix II GX devices
Contains 4-, 8-, and 16-Mb flash memories for configuration data storage
On-chip decompression feature almost doubles the effective configuration density
Standard flash die and a controller die combined into single stacked chip package
External flash interface supports parallel programming of flash and external processor access to
unused portions of memory
Flash memory block or sector protection capability using the external flash interface
Supported in EPC4 and EPC16 devices
Page mode support for remote and local reconfiguration with up to eight configurations for the entire
system
Compatible with Stratix series remote system configuration feature
Supports byte-wide configuration mode fast passive parallel (FPP) with an 8-bit data output per DCLK
cycle
Supports true n-bit concurrent configuration (n = 1, 2, 4, and 8) of Altera FPGAs
Pin selectable 2-ms or 100-ms power-on reset (POR) time
Configuration clock supports programmable input source and frequency synthesis
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of its semiconductor products to current specifications in accordance with Altera's standard warranty, but reserves the right to make changes to any
products and services at any time without notice. Altera assumes no responsibility or liability arising out of the application or use of any information,
product, or service described herein except as expressly agreed to in writing by Altera. Altera customers are advised to obtain the latest version of device
specifications before relying on any published information and before placing orders for products or services.
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9001:2008
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101 Innovation Drive, San Jose, CA 95134
Multiple configuration clock sources supported (internal oscillator and external clock input pin)
External clock source with frequencies up to 100 MHz
Internal oscillator defaults to 10 MHz and you can program the internal oscillator for higher frequen‐
cies of 33, 50, and 66 MHz
Clock synthesis supported using user programmable divide counter
Available in the 100-pin plastic quad flat pack (PQFP) and the 88-pin Ultra FineLine BGA (UFBGA)
packages
Vertical migration between all devices supported in the 100-pin PQFP package
Supply voltage of 3.3 V (core and I/O)
Hardware compliant with IEEE Std. 1532 in-system programmability (ISP) specification
Supports ISP using Jam Standard Test and Programming Language (STAPL)
Supports JTAG boundary scan
The nINIT_CONF pin allows private JTAG instruction to start FPGA configuration
Internal pull-up resistor on the nINIT_CONF pin always enabled
User programmable weak internal pull-up resistors on nCS and OE pins
Internal weak pull-up resistors on external flash interface address and control lines, bus hold on data
lines
Standby mode with reduced power consumption
Note: For more information about FPGA configuration schemes and advanced features, refer to the
configuration chapter in the appropriate device handbook.
Functional Description
The Altera EPC device is a single device with high speed and advanced configuration solution for high-
density FPGAs. The core of an EPC device is divided into two major blocks—a configuration controller
and a flash memory. The flash memory is used to store configuration data for systems made up of one or
more than one Altera FPGAs. Unused portions of the flash memory can be used to store processor code
or data that can be accessed using the external flash interface after the FPGA configuration is complete.
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Table 2: Supported EPC devices required to configure an ACEX 1K, APEX 1K, APEX 20K, APEX 20KC, APEX
20KE, APEX II, Arria GX, Cyclone, Cyclone II, FLEX 10K, FLEX 10KA, FLEX 10KE, Stratix, Stratix GX, Stratix II,
Stratix II GX, or Mercury device.
Device Family Device Data Size (Bits)
(1)
EPC Devices(2)
EPC4 EPC8 EPC16
Arria GX
EP1AGX20C 9,640,672 1
EP1AGX35C
EP1AGX35D 9,640,672 1
EP1AGX50C
EP1AGX50D
16,951,824 1EP1AGX60C
EP1AGX60D
EP1AGX60E 16,951,824 1
EP1AGX90E 25,699,104 1
Stratix
EP1S10 3,534,640 1 1 1
EP1S20 5,904,832 1 1 1
EP1S25 7,894,144 1 1
EP1S30 10,379,368 1 1
EP1S40 12,389,632 1 1
EP1S60 17,543,968 1
EP1S80 23,834,032 1
Stratix GX
EP1SGX10 3,534,640 1 1 1
EP1SGX25 7,894,144 1 1
EP1SGX40 12,389,632 1 1
Stratix II
EP2S15 4,721,544 1 1 1
EP2S30 9,640,672 1 1
EP2S60 16,951,824 1
EP2S90 25,699,104
EP2S130 37,325,760
EP2S180 49,814,760
(1) The Raw Binary File (.rbf) sizes are used to determine the data size for each device.
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Device Family Device Data Size (Bits)
(1)
EPC Devices(2)
EPC4 EPC8 EPC16
Stratix II
GX
EP2SGX30C 9,640,672 1
EP2SGX30D 9,640,672 1
EP2SGX60C 16,951,824 1
EP2SGX60D 16,951,824 1
EP2SGX60E 16,951,824 1
EP2SGX90E 25,699,104
EP2SGX90F 25,699,104
EP2SGX130G 37,325,760
Cyclone
EP1C3 627,376 1 1 1
EP1C4 924,512 1 1 1
EP1C6 1,167,216 1 1 1
EP1C12 2,326,528 1 1 1
EP1C20 3,559,608 1 1 1
Cyclone II
EP2C5 1,223,980 1 1 1
EP2C8 1,983,792 1 1 1
EP2C20 3,930,986 1 1 1
EP2C35 7,071,234 1 1
EP2C50 9,122,148 1 1
EP2C70 10,249,694 1 1
ACEX 1K
EP1K10 159,160 1 1 1
EP1K30 473,720 1 1 1
EP1K50 784,184 1 1 1
EP1K100 1,335,720 1 1 1
APEX 20K
EP20K100 993,360 1 1 1
EP20K200 1,950,800 1 1 1
EP20K400 3,880,720 1 1 1
(1) The Raw Binary File (.rbf) sizes are used to determine the data size for each device.
(2) These values are calculated with the compression feature of the EPC device enabled.
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Device Family Device Data Size (Bits)
(1)
EPC Devices(2)
EPC4 EPC8 EPC16
APEX 20KC
EP20K200C 1,968,016 1 1 1
EP20K400C 3,909,776 1 1 1
EP20K600C 5,673,936 1 1 1
EP20K1000C 8,960,016 1 1
APEX 20KE
EP20K30E 354,832 1 1 1
EP20K60E 648,016 1 1 1
EP20K100E 1,008,016 1 1 1
EP20K160E 1,524,016 1 1 1
EP20K200E 1,968,016 1 1 1
EP20K300E 2,741,616 1 1 1
EP20K400E 3,909,776 1 1 1
EP20K600E 5,673,936 1 1 1
EP20K1000E 8,960,016 1 1
EP20K1500E 12,042,256 1 1
APEX II
EP2A15 4,358,512 1 1 1
EP2A25 6,275,200 1 1 1
EP2A40 9,640,528 1 1
EP2A70 17,417,088 1
Table 3: Supported Flash Memory for EPC Devices
Device Family Grade Package Flash Memory
Leaded Lead-Fee
EPC4 Commercial PQFP 100 Intel or Micron Intel or Micron
Industrial PQFP 100 Intel or Micron Intel
EPC8 Commercial/Industrial PQFP 100 Intel or Sharp Intel
(1) The Raw Binary File (.rbf) sizes are used to determine the data size for each device.
(2) These values are calculated with the compression feature of the EPC device enabled.
(2) These values are calculated with the compression feature of the EPC device enabled.
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Device Family Grade Package Flash Memory
Leaded Lead-Fee
EPC16
Commercial UBGA 884 Intel or Sharp Intel or Sharp
Industrial UBGA 884 Intel or Sharp Intel
Military UBGA 884 Intel Intel
Commercial/Industrial PQFP 100 Intel or Sharp Intel
Note: The external flash interface feature is supported in EPC4 and EPC16 devices. For more information
about using this feature in the EPC8 device, contact Altera for support.
EPC devices have a 3.3-V core and I/O interface. The controller chip is a synchronous system that
implements the various interfaces and features. The controller chip features three separate interfaces:
A configuration interface between the controller and the Altera FPGAs
A JTAG interface on the controller that enables ISP of the flash memory
An external flash interface that the controller shares with an external processor or FPGA
implementing a Nios embedded processor—an interface available after ISP and configuration
Figure 1: EPC Device Block Diagram
Flash FPGA
Controller
JTAG/ISP Interface
Enhanced Configuration Device
Shared Flash Interface
Shared Flash
Interface
The EPC device features multiple configuration schemes. In addition to supporting the traditional passive
serial (PS) configuration scheme for a single device or a serial-device chain, the EPC device features
concurrent configuration and parallel configuration. With the concurrent configuration scheme, up to
eight PS device chains can be configured simultaneously. In the FPP configuration scheme, 8-bits of data
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are clocked into the FPGA during each cycle. These configuration schemes offer significantly reduced
configuration times over traditional schemes.
Furthermore, the EPC device features a dynamic configuration or page mode feature. This feature allows
you to dynamically reconfigure all the FPGAs in your system with new images stored in the configuration
memory. Up to eight different system configurations or pages can be stored in the memory and selected
using the PGM[2..0] pins. Your system can be dynamically reconfigured by selecting one of the eight
pages and initiating a reconfiguration cycle.
This page mode feature combined with the external flash interface allows remote and local updates of
system configuration data. The EPC devices are compatible with the remote system configuration feature
of the Stratix device.
Other user programmable features include:
Real-time decompression of configuration data
Programmable configuration clock (DCLK)
Flash ISP
Programmable POR delay (PORSEL)
Related Information
PCN0506: Addition of Intel Flash Memory As Source for EPC4, EPC8, and EPC16 Enhanced
Configuration Devices
Provides more information about EPC devices, refer to the PCN0506: Addition of Intel Flash Memory
As
Stratix Device Handbook.
FPGA Configuration
FPGA configuration is managed by the configuration controller chip. This process includes reading
configuration data from the flash memory, decompressing the configuration data, transmitting configura‐
tion data using the appropriate DATA[] pins, and handling error conditions.
After POR, the controller determines the user-defined configuration options by reading its option bits
from the flash memory. These options include the configuration scheme, configuration clock speed,
decompression, and configuration page settings. The option bits are stored at flash address location
0x8000 (word address) and occupy 512-bits or 32-words of memory. These options bits are read using the
internal flash interface and the default 10 MHz internal oscillator.
After obtaining the configuration settings, the configuration controller chip checks if the FPGA is ready to
accept configuration data by monitoring the nSTATUS and CONF_DONE signals. When the FPGA is ready
(nSTATUS is high and CONF_DONE is low), the controller begins data transfer using the DCLK and DATA[]
output pins. The controller selects the configuration page to be transmitted to the FPGA by sampling its
PGM[2..0] pins after POR or reset.
The function of the configuration unit is to transmit decompressed data to the FPGA, depending on the
configuration scheme. The EPC device supports four concurrent configuration modes, with n = 1, 2, 4, or
8 (where n is the number of bits that are sent per DCLK cycle on the DATA[n] signals). The value n = 1
corresponds to the traditional PS configuration scheme. The values n = 2, 4, and 8 correspond to
concurrent configuration of 2, 4, or 8 different PS configuration chains, respectively. Additionally, the
FPGA can be configured in FPP mode, where eight bits of DATA are clocked into the FPGA per DCLK cycle.
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Depending on the configuration bus width (n), the circuit shifts uncompressed configuration data to the
valid DATA[n] pins. Unused DATA[] pins drive low.
In addition to transmitting configuration data to the FPGAs, the configuration circuit is also responsible
for pausing configuration whenever there is insufficient data available for transmission. This occurs when
the flash read bandwidth is lower than the configuration write bandwidth. Configuration is paused by
stopping the DCLK to the FPGA, when waiting for data to be read from the flash or for data to be
decompressed. This technique is called “Pausing DCLK”.
The EPC device flash-memories feature a 90-ns access time (approximately 10 MHz). Hence, the flash
read bandwidth is limited to about 160 megabits per second (Mbps) (16-bit flash data bus, DQ[], at 10
MHz). However, the configuration speeds supported by Altera FPGAs are much higher and translate to
high configuration write bandwidths. For example, 100-MHz Stratix FPP configuration requires data at
the rate of 800 Mbps (8-bit DATA[] bus at 100MHz). This is much higher than the 160 Mbps the flash
memory can support and is the limiting factor for configuration time. Compression increases the effective
flash-read bandwidth as the same amount of configuration data takes up less space in the flash memory
after compression. Since Stratix configuration data compression ratios are approximately two, the
effective read bandwidth doubles to about 320 Mbps.
Finally, the configuration controller also manages errors during configuration. A CONF_DONE error occurs
when the FPGA does not de-assert its CONF_DONE signal within 64 DCLK cycles after the last bit of configu‐
ration data is transmitted. When a CONF_DONE error is detected, the controller pulses the OE line low,
which pulls the nSTATUS signal low and triggers another configuration cycle.
A cyclic redundancy check (CRC) error occurs when the FPGA detects corruption in the configuration
data. This corruption could be a result of noise coupling on the board such as poor signal integrity on the
configuration signals. When this error is signaled by the FPGA (by driving the nSTATUS signal low), the
controller stops configuration. If the Auto-Restart Configuration After Error option is enabled in the
FPGA, it releases its nSTATUS signal after a reset time-out period and the controller attempts to
reconfigure the FPGA.
After the FPGA configuration process is complete, the controller drives the DCLK pin low and the DATA[]
pins high. Additionally, the controller tri-states its internal interface to the flash memory, enables the
weak internal pull-ups on the flash address and control lines, and enables bus-keep circuits on flash data
lines.
The following sections describe the different configuration schemes supported by the EPC device—FPP,
PS, and concurrent configuration schemes.
Configuration Signals
Table 4: Configuration Signals Connections Between EPC device and Altera FPGAs.
EPC Device Pin Altera FPGA Pin Description
DATA[] DATA[] Configuration data transmitted from the EPC device to the FPGA,
which is latched on the rising edge of DCLK.
DCLK DCLK EPC device generated clock used by the FPGA to latch configuration
data provided on the DATA[] pins.
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EPC Device Pin Altera FPGA Pin Description
nINIT_CONF nCONFIG Open-drain output from the EPC device that is used to start FPGA
reconfiguration using the initiate configuration (INIT_CONF) JTAG
instruction. This connection is not needed if the INIT_CONF JTAG
instruction is not needed. If nINIT_CONF is not connected to nCONFIG,
nCONFIG must be tied to VCC either directly or through a pull-up
resistor.
OE nSTATUS Open-drain bidirectional configuration status signal, which is driven
low by either the EPC device or FPGA during POR and to signal an
error during configuration. Low pulse on OE resets the EPC device
controller.
nCS CONF_DONE Configuration done output signal driven by the FPGA.
Fast Passive Parallel Configuration
Stratix series and APEX II devices can be configured using the EPC device in the FPP configuration mode.
In this mode, the EPC device sends a byte of data on the DATA[7..0] pins, which connect to the
DATA[7..0] input pins of the FPGA, per DCLK cycle. Stratix series and APEX II FPGAs receive byte-wide
configuration data per DCLK cycle. The following figure shows the EPC device in FPP configuration mode.
In this figure, the external flash interface is not used and hence most flash pins are left unconnected (with
the few noted exceptions).
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Figure 2: FPP Configuration Connection Guideline
Enhanced Configuration Device
DCLK
DATA[7..0]
OE
nCS
nINIT_CONF (2)
MSEL DCLK
DATA[7..0]
nSTATUS
CONF_DONE
nCONFIG
VCC VCC
GND
GND
(3) (3)
nCE
EXCLK
Stratix Series
or
APEX II Device WE#C
RP#C
WP#
PORSEL
PGM[2..0]
TMO
WE#F
RP#F
A[20..0]
RY/BY#
CE#
OE#
DQ[15..0]
VCC
N.C.
N.C.
N.C.
N.C.
N.C.
BYTE# (5)
TM1
(3)
(3)
C-A0 (5)
C-A1 (5)
C-A15 (5)
C-A16 (5)
A0-F
A1-F
A15-F
A16-F
(1) (1)
n
(6)
(1)
nCEO
N.C.
(4)
(4)
(4)
VCCW
VCC (7)
Notes:
(1) The VCC should be connected to the same supply voltage as the EPC device.
(2) The nINIT_CONF pin is available on EPC devices and has an internal pull-up resistor that is always active. This means an external pull-up
resistor is not required on the nINIT_CONF or nCONFIG signal. The nINIT_CONF pin does not need to be connected if its functionality is not
used. If nINIT_CONF is not used, nCONFIG must be pulled to VCC either directly or through a resistor.
(3) The EPC devices’ OE and nCS pins have internal programmable pull-up resistors. If internal pull-up resistors are used, external pull-up resistors
should not be used on these pins. The internal pull-up resistors are used by default in the Quartus II software. To turn off the internal pull-up
resistors, check the Disable nCS and OE pull-ups on configuration device option when generating programming files.
(4) For PORSEL, PGM[], and EXCLK pin connections, refer to JTAG Interface Pins and Other Required Controller Pins table.
(5) In the 100-pin PQFP package, you must externally connect the following pins: C-A0 to F-A0, C-A1 to F-A1, C-A15 to F-A15, C-A16 to
F-A16, and BYTE# to VCC. Additionally, you must make the following pin connections in both 100-pin PQFP and 88-pin UFBGA packages: C-RP#
to F-RP#, C-WE# to F-WE#, TM1 to VCC, TM0 to GND, and WP# to VCC.
(6) Connect the FPGA MSEL[] input pins to select the FPP configuration mode. For more information, refer to the configuration chapter in the
appropriate device handbook.
(7) To protect Intel Flash-based EPC devices content, isolate the VCCW supply from VCC. For more information, refer to “Intel Flash-Based EPC Device
Protection.
Multiple FPGAs can be configured using a single EPC device in FPP mode. In this mode, multiple Stratix
series FPGAs, APEX II FPGAs, or both, are cascaded together in a daisy chain.
After the first FPGA completes configuration, its nCEO pin asserts to activate the nCE pin for the second
FPGA, which prompts the second device to start capturing configuration data. In this setup, the FPGAs
CONF_DONE pins are tied together, and hence all devices initialize and enter user mode simultaneously. If
the EPC device or one of the FPGAs detects an error, configuration stops (and simultaneously restarts) for
the whole chain because the nSTATUS pins are tied together.
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Note: While Altera FPGAs can be cascaded in a configuration chain, the EPC devices cannot be cascaded
to configure larger devices or chains.
Related Information
Stratix Device Handbook
Provides more information about remotely updating Stratix FPGAs.
Passive Serial Configuration
APEX 20KC, APEX 20KE, APEX 20K, APEX II, Cyclone series, FLEX 10K, and Stratix series devices can
be configured using EPC devices in the PS mode. This mode is similar to the FPP mode, with the
exception that only one bit of data (DATA[0]) is transmitted to the FPGA per DCLK cycle. The remaining
DATA[7..1] output pins are unused in this mode and driven low.
The configuration schematic for PS configuration of a single FPGA or single-serial chain is identical to the
FPP schematic, with the exception that only DATA[0] output from the EPC device connects to the FPGA
DATA0 input pin and the remaining DATA[7..1] pins are left floating.
Concurrent Configuration
EPC devices support concurrent configuration of multiple FPGAs (or FPGA chains) in PS mode.
Concurrent configuration is when the EPC device simultaneously outputs n bits of configuration data on
the DATA[n-1..0] pins (n = 1, 2, 4, or 8), and each DATA[] line serially configures a different FPGA chain.
The number of concurrent serial chains is user-defined using the Quartus II software and can be any
number from 1 to 8. For example, for three concurrent chains, you can select the 4-bit PS mode and
connect the least significant DATA bits to the FPGAs or FPGA chains. Leave the most significant DATA bit
(DATA[3]) unconnected. Similarly, for 5-, 6-, or 7-bit concurrent chains you can select the 8-bit PS mode.
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Figure 3: Concurrent Configuration of Multiple FPGAs in PS Mode (n = 8)
DCLK
DATA0
nSTATUS
CONF_DONE
nCONFIG
VCC
GND
(3)
nCE
(3)
FPGA0
VCC
DCLK
DATA0
nCONFIG
nCE
DCLK
DATA0
GND
GND
FPGA1
FPGA7
Enhanced Configuration Device
DCLK
DATA0
OE
nCS
nINIT_CONF (2)
WE#C
RP#C WE#F
RP#F
A[20..0]
RY/BY#
CE#
OE#
DQ[15..0]
DATA1
nSTATUS
CONF_DONE
nSTATUS
CONF_DONE
nCONFIG
nCE
DATA 7
N.C.
N.C.
N.C.
N.C.
N.C.
(3)
(3)
EXCLK
PORSEL
PGM[2..0]
GND
TMO
WP#
VCC
VCCW
BYTE# (5)
TM1
C-A0 (5)
C-A1 (5)
C-A15 (5)
C-A16 (5)
A0-F
A1-F
A15-F
A16-F
MSEL
MSEL
MSEL
n
n
n
(6)
(6)
(6)
(1) (1)
nCEON.C.
nCEON.C.
nCEON.C.
(1)
(4)
(4)
(4)
VCC (7)
Notes:
(1) Connect VCC to the same supply voltage as the EPC device.
(2) The nINIT_CONF pin is available on EPC devices and has an internal pull-up resistor that is always active. This means an external pull-up
resistor is not required on the nINIT_CONF or nCONFIG signal. The nINIT_CONF pin does not need to be connected if its functionality is not
used. If nINIT_CONF is not used, nCONFIG must be pulled to VCC either directly or through a resistor.
(3) The EPC devices’ OE and nCS pins have internal programmable pull-up resistors. If internal pull-up resistors are used, external pull-up resistors
should not be used on these pins. The internal pull-up resistors are used by default in the Quartus II software. To turn off the internal pull-up
resistors, check the Disable nCS and OE pull-ups on configuration device option when generating programming files.
(4) For PORSEL, PGM[], and EXCLK pin connections, refer to Interface Pins and Other Required Controller Pins table.
(5) In the 100-pin PQFP package, you must externally connect the following pins: C-A0 to F-A0, C-A1 to F-A1, C-A15 to F-A15, C-A16 to F-A16,
and BYTE# to VCC. Additionally, you must make the following pin connections in both 100-pin PQFP and 88-pin UFBGA packages: C-RP# to FRP#,
C-WE# to F-WE#, TM1 to VCC, TM0 to GND, and WP# to VCC.
(6) Connect the FPGA MSEL[] input pins to select the PS configuration mode. For more information, refer to the configuration chapter in the
appropriate device handbook.
(7) To protect Intel Flash based EPC devices content, isolate the VCCW supply from VCC. For more information, refer to “Intel Flash-Based EPC Device
Protection” .
Table 5: Supported PS Configuration Mode in EPC Devices
Mode Name Mode (n =)(3) Used Outputs Unused Outputs
PS mode 1 DATA0 DATA[7..1] drive low
Multi-device PS 2 DATA[1..0] DATA[7..2] drive low
(3) This is the number of valid DATA outputs for each configuration mode.
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Mode Name Mode (n =)(3) Used Outputs Unused Outputs
Multi-device PS 4 DATA[3..0] DATA[7..4] drive low
Multi-device PS 8 DATA[7..0]
External Flash Interface
The EPC devices support external FPGA or processor access to its flash memory. The unused portions of
the flash memory can be used by the external device to store code or data. This interface can also be used
in systems that implement remote configuration capabilities. Configuration data within a particular
configuration page can be updated using the external flash interface and the system could be reconfigured
with the new FPGA image. This interface is also useful to store Nios boot code, application code, or both.
The address, data, and control ports of the flash memory are internally connected to the EPC device
controller and external device pins. An external source can drive these external device pins to access the
flash memory when the flash interface is available.
This external flash interface is a shared bus interface with the configuration controller chip. The configu‐
ration controller is the primary bus master. Since there is no bus arbitration support, the external device
can only access the flash interface when the controller has tri-stated its internal interface to the flash.
Simultaneous access by the controller and the external device will cause contention, and result in configu‐
ration and programming failures.
Since the internal flash interface is directly connected to the external flash interface pins, controller flash
access cycles will toggle the external flash interface pins. The external device must be able to tri-state its
flash interface during these operations and ignore transitions on the flash interface pins.
Note: The external flash interface signals cannot be shared between multiple EPC devices because this
causes contention during ISP and configuration. During these operations, the controller chips
inside the EPC devices are actively accessing flash memory. Therefore, EPC devices do not support
shared flash bus interfaces.
The EPC device controller chip accesses flash memory during:
FPGA configuration—reading configuration data from flash
JTAG-based flash programming—storing configuration data in flash
At POR—reading option bits from flash
During these operations, the external FPGA or processor must tri-state its interface to the flash memory.
After configuration and programming, the EPC device’s controller tri-states the internal interface and
goes into an idle mode. To interrupt a configuration cycle in order to access the flash using the external
flash interface, the external device can hold the FPGA’s nCONFIG input low. This keeps the configura‐
tion device in reset by holding the nSTATUS-OE line low, allowing external flash access.
(3) This is the number of valid DATA outputs for each configuration mode.
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Figure 4: FPP Configuration with External Flash Interface
For external flash interface support in the EPC8 device, contact Altera for support.
C-A0 (2)
C-A1 (2)
C-A15 (2)
C-A16 (2)
A0-F
A1-F
A15-F
A16-F
(4)
(4)
MSEL DCLK
DATA[7..0]
nSTATUS
CONF_DONE
nCONFIG
VCC VCC
GND
nCE
Stratix Series
or
APEX II Device WE#
RP#
A[20..0]
RY/BY#
CE#
OE#
DQ[15..0]
PLD or Processor
Enhanced Configuration Device
DCLK
DATA[7..0]
OE
nCS
nINIT_CONF
WE#C
RP#C WE#F
RP#F
A[20..0](1)
RY/BY#(5)
CE#
OE#
DQ[15..0]
GND
EXCLK
WP#
PORSEL
PGM[2..0]
TMO
VCC
VCCW
BYTE# (2)
TM1
n
nCEON.C.
VCC(5)
(3)
(3)
(3)
(1) Pin A20 in EPC16 devices, pins A20 and A19 in EPC8 devices, and pins A20, A19, and A18 in EPC4 devices should be left floating. These pins
should not be connected to any signal as they are NC pins.
(2) In the 100-pin PQFP package, you must externally connect the following pins: C-A0 to F-A0, C-A1 to F-A1, C-A15 to F-A15, C-A16 to
F-A16, and BYTE# to VCC. Additionally, you must make the following pin connections in both 100-pin PQFP and 88-pin UFBGA packages:
C-RP# to F-RP#, C-WE# to F-WE#, TM1 to VCC, TM0 to GND, and WP# to VCC.
(3) For PORSEL, PGM[], and EXCLK pin connections, refer to JTAG Interface Pins and Other Required Controller Pins table.
(4) RY/BY# pin is only available for Sharp flash-based EPC8 and EPC16 devices.
(5) To protect Intel Flash based EPC devices content, isolate the VCCW supply from VCC. For more information, refer to “Intel Flash-Based EPC Device
Protection” .
Related Information
Altera Enhanced Configuration Devices
Provides more information about the software support for the external flash interface feature.
Intel Flash-Based EPC Device Protection
In the absence of the lock bit protection feature in the EPC4, EPC8, and EPC16 devices with Intel flash,
Altera recommends four methods to protect the Intel Flash content in EPC4, EPC8, and EPC16 devices.
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Any method alone is sufficient to protect the flash. The methods are listed here in the order of descending
protection level:
1. Using an RP# of less than 0.3 V on power-up and power-down for a minimum of 100 ns to a
maximum 25 ms disables all control pins, making it impossible for a write to occur.
2. Using VPP < VPPLK, where the maximum value of VPPLK is 1 V, disables writes. VPP < VPPLK
means programming or writes cannot occur. VPP is a programming supply voltage input pin on the
Intel flash. VPP is equivalent to the VCCW pin on EPC devices.
3. Using a high CE# disables the chip. The requirement for a write is a low CE# and low WE#. A high
CE# by itself prevents writes from occurring.
4. Using a high WE# prevent writes because a write only occurs when the WE# is low.
Performing all four methods simultaneously is the safest protection for the flash content.
The following lists the ideal power-up sequence:
1. Power up VCC.
2. Maintain VPP < VPPLK until VCC is fully powered up.
3. Power up VPP .
4. Drive RP# low during the entire power-up process. RP# must be released high within 25 ms after VPP
is powered up.
Note: CE# and WE# must be high for the entire power-up sequence.
The following lists the ideal power-down sequence:
1. Drive RP# low for 100 ns before power-down.
2. Power down VPP < VPPLK.
3. Power down VCC.
4. Drive RP# low during the entire power-down process.
Note: CE# and WE# must be high for the entire power-down sequence
The RP# pin is not internally connected to the controller. Therefore, an external loop-back connection
between C-RP# and F-RP# must be made on the board even when you are not using the external device to
the RP# pin with the loop-back connection. Always tri-state RP# when the flash is not in use.
If an external power up monitoring circuit is connected to the RP# pin with the loop-back connection, use
the following guidelines to avoid contention on the RP# line:
The power-up sequence on the 3.3-V supply should complete within 50 ms of power up. The 3.3-V
VCC should reach the minimum VCC before 50 ms and RP# should then be released.
RP# should be driven low by the power-up monitoring circuit during power up. After power up, RP#
should be tri-stated externally by the power-up monitoring circuit.
If the preceding guidelines cannot be completed within 50 ms, then the OE pin must be driven low
externally until RP# is ready to be released.
Dynamic Configuration (Page Mode)
The dynamic configuration (or page mode) feature allows the EPC device to store up to eight different
sets of designs for all the FPGAs in your system. You can then choose which page (set of configuration
files) the EPC device should use for FPGA configuration.
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Dynamic configuration or the page mode feature enables you to store a minimum of two pages—a factory
default or fail-safe configuration and an application configuration. The fail-safe configuration page could
be programmed during system production, while the application configuration page could support
remote or local updates. These remote updates could add or enhance system features and performance.
However, with remote update capabilities comes the risk of possible corruption of configuration data. In
the event of such a corruption, the system could automatically switch to the fail-safe configuration and
avoid system downtime.
The EPC device page mode feature works with the Stratix remote system configuration feature, to enable
intelligent remote updates to your systems.
The three PGM[2..0] input pins control which page is used for configuration and these pins are sampled
at the start of each configuration cycle when OE goes high. The page mode selection allows you to
dynamically reconfigure the functionality of your FPGA by switching the PGM[2..0] pins and asserting
nCONFIG. Page 0 is defined as the default page and the PGM[2] pin is the MSB.
Note: The PGM[2..0] input pins must not be left floating on your board. When you are not using this
feature, connect the PGM[2..0] pins to GND to select the default page 000.
The EPC device pages are dynamically-sized regions in memory. The start address and length of each
page is programmed into the option-bit space of the flash memory during initial programming. All
subsequent configuration cycles sample the PGM[] pins and use the option-bit information to jump to the
start of the corresponding configuration page. Each page must have configuration files for all FPGAs in
your system that are connected to that EPC device.
For example, if your system requires three configuration pages and includes two FPGAs, each page will
store two SRAM Object Files (.sof) for a total of six .sof in the configuration device.
Furthermore, all EPC device configuration schemes (PS, FPP, and concurrent PS) are supported with the
page-mode feature. The number of pages, devices, or both, that can be configured using a single EPC
device is only limited by the size of the flash memory.
Related Information
Stratix Device Handbook
Provides more information about remotely updating Stratix FPGAs.
Altera Enhanced Configuration Devices
Provides more information about the page-mode feature implementation and programming file
generation steps using the Quartus II software.
Real-Time Decompression
EPC devices support on-chip real time decompression of configuration data. FPGA configuration data is
compressed by the Quartus II software and stored in the EPC device. During configuration, the
decompression engine inside the EPC device will decompress or expand configuration data. This feature
increases the effective-configuration density of the EPC device up to 7, 15, or 30 Mb in the EPC4, EPC8,
and EPC16 devices, respectively.
The EPC device also supports a parallel 8-bit data bus to the FPGA to reduce configuration time.
However, in some cases, the FPGA data-transfer time is limited by the flash-read bandwidth. For example,
when configuring an APEX II device in FPP (byte-wide data per cycle) mode at a configuration speed of
66 MHz, the FPGA write bandwidth is equal to 8 bits × 66 MHz = 528 Mbps. The flash read interface,
however, is limited to approximately 10 MHz (since the flash access time is ~90 ns). This translates to a
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flash-read bandwidth of 16 bits × 10 MHz = 160 Mbps. Hence, the configuration time is limited by the
flash-read time.
When configuration data is compressed, the amount of data that needs to be read out of the flash is
reduced by about 50%. If 16 bits of compressed data yields 30 bits of uncompressed data, the flash-read
bandwidth increases to 30 bits × 10 MHz = 300 Mbps, reducing overall configuration time.
You can enable the controller's decompression feature in the Quartus II software, Configuration Device
Options window by turning on Compression Mode.
Note: The decompression feature supported in the EPC devices is different from the decompression
feature supported by the Stratix II FPGAs and the Cyclone series. When configuring Stratix II
FPGAs or the Cyclone series using EPC devices, Altera recommends enabling decompression in
Stratix II FPGAS or the Cyclone series only for faster configuration.
The compression algorithm used in Altera devices is optimized for FPGA configuration bitstreams. Since
FPGAs have several layers of routing structures (for high performance and easy routability), large
amounts of resources go unused. These unused routing and logic resources as well as un-initialized
memory structures result in a large number of configuration RAM bits in the disabled state. Altera's
proprietary compression algorithm takes advantage of such bitstream qualities.
The general guideline for effectiveness of compression is the higher the device logic or routing utilization,
the lower the compression ratio (where the compression ratio is defined as the original bitstream size
divided by the compressed bitstream size).
For Stratix designs, based on a suite of designs with varying amounts of logic utilization, the minimum
compression ratio was observed to be 1.9 or a ~47% size reduction for these designs. The following table
lists the sample compression ratios from a suite of Stratix designs. These numbers serve as a guideline, not
a specification, to help you allocate sufficient configuration memory to store compressed bitstreams.
Table 6: Stratix Compression Ratios
These numbers are preliminary. They are intended to serve as a guideline, not a specification.
Item Minimum Average
Logic Utilization 98% 64%
Compression Ratio 1.9 2.3
% Size Reduction 47% 57%
Programmable Configuration Clock
The configuration clock (DCLK) speed is user programmable. One of two clock sources can be used to
synthesize the configuration clock; a programmable oscillator or an external clock input pin (EXCLK). The
configuration clock frequency can be further synthesized using the clock divider circuitry. This clock can
be divided by the N counter to generate your DCLK output. The N divider supports all integer dividers
between 1 and 16, as well as a 1.5 divider and a 2.5 divider. The duty cycle for all clock divisions other
than non-integer divisions is 50% (for the non-integer dividers, the duty cycle will not be 50%).
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Enhanced Configuration (EPC) Devices Datasheet Altera Corporation
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Figure 5: Clock Divider Unit
The DCLK frequency is limited by the maximum DCLK frequency the FPGA supports.
Note: For more information about the maximum DCLK input frequency supported by the FPGA, refer
to the configuration chapter in the appropriate device handbook.
Configuration Device
Clock Divider Unit
Divide
by N
External Clock
(Up to 100 MHz)
Internal Oscillator
10 MHz
33 MHz
50 MHz
66 MHz
DCLK
The controller chip features a programmable oscillator that can output four different frequencies. The
various settings generate clock outputs at frequencies as high as 10, 33, 50, and 66 MHz.
Table 7: Internal Oscillator Frequencies
Frequency Setting Min (MHz) Typ (MHz) Max (MHz)
10 6.4 8.0 10.0
33 21.0 26.5 33.0
50 32.0 40.0 50.0
66 42.0 53.0 66.0
Clock source, oscillator frequency, and clock divider (N) settings can be made in the Quartus II software,
by accessing the Configuration Device Options inside the Device Settings window or the Convert
Programming Files window. The same window can be used to select between the internal oscillator and
the external clock (EXCLK) input pin as your configuration clock source. The default setting selects the
internal oscillator at the 10 MHz setting as the clock source, with a divide factor of 1.
Related Information
Altera Enhanced Configuration Devices
Provides more information about making the configuration clock source, frequency, and divider settings.
Flash In-System Programming (ISP)
The flash memory inside EPC devices can be programmed in-system using the JTAG interface and the
external flash interface. JTAG-based programming is facilitated by the configuration controller in the EPC
device. External flash interface programming requires an external processor or FPGA to control the flash.
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Note: The EPC device flash memory supports 100,000 erase cycles.
JTAG-based Programming
The IEEE Std. 1149.1 JTAG Boundary Scan is implemented in EPC devices to facilitate the testing of its
interconnection and functionality. EPC devices also support the ISP mode. The EPC device is compliant
with the IEEE Std. 1532 draft 2.0 specification.
The JTAG unit of the configuration controller communicates directly with the flash memory. The
controller processes the ISP instructions and performs the necessary flash operations. EPC devices
support the maximum JTAG TCK frequency of 10 MHz.
During JTAG-based ISP, the external flash interface is not available. Before the JTAG interface programs
the flash memory, an optional JTAG instruction (PENDCFG) can be used to assert the FPGA’s nCONFIG pin
(using the nINIT_CONF pin). This will keep the FPGA in reset and terminate any internal flash access. This
function prevents contention on the flash pins when both JTAG ISP and an external FPGA or processor
try to access the flash simultaneously. The nINIT_CONF pin is released when the initiate configuration
(nINIT_CONF) JTAG instruction is updated. As a result, the FPGA is configured with the new configura‐
tion data stored in flash.
You can add an initiate configuration (nINIT_CONF) JTAG instruction to your programming file in the
Quartus II software by enabling the Initiate configuration after programming option in the
Programmer options window (Options menu).
Programming using External Flash Interface
This method allows parallel programming of the flash memory using the 16-bit data bus. An external
processor or FPGA acts as the flash controller and has access to programming data using a communica‐
tion link such as UART, Ethernet, and PCI. In addition to the program, erase, and verify operations, the
external flash interface supports block or sector protection instructions.
External flash interface programming is only allowed when the configuration controller has relinquished
flash access by tri-stating its internal interface. If the controller has not relinquished flash access during
configuration or JTAG-based ISP, you must hold the controller in reset before initiating external
programming. The controller can be reset by holding the FPGA nCONFIG line at a logic low level. This
keeps the controller in reset by holding the nSTATUS-OE line low, allowing external flash access.
Note: If initial programming of the EPC device is done in-system using the external flash interface, the
controller must be kept in reset by driving the FPGA nCONFIG line low to prevent contention on
the flash interface.
Pin Description
The following tables list the EPC device pins. These tables include configuration interface pins, external
flash interface pins, JTAG interface pins, and other pins.
Table 8: Configuration Interface Pins
Pin Name Pin Type Description
DATA [7..0] Output Configuration data output bus. DATA changes on each falling edge of
DCLK. DATA is latched into the FPGA on the rising edge of DCLK.
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Pin Name Pin Type Description
DCLK Output The DCLK output pin from the EPC device serves as the FPGA configu‐
ration clock. DATA is latched by the FPGA on the rising edge of DCLK.
nCS Input The nCS pin is an input to the EPC device and is connected to the
FPGA’s CONF_DONE signal for error detection after all configuration
data is transmitted to the FPGA. The FPGA will always drive nCS and
OE low when nCONFIG is asserted. This pin contains a programmable
internal weak pull-up resistor of 6 KW that can be disabled or enabled
in the Quartus II software through the Disable nCS and OE pull-ups
on configuration device option.
nINIT_CONF Open-Drain
Output The nINIT_CONF pin can be connected to the nCONFIG pin on the
FPGA to initiate configuration from the EPC device using a private
JTAG instruction. This pin contains an internal weak pull-up resistor
of 6K W that is always active. The INIT_CONF pin does not need to be
connected if its functionality is not used. If nINIT_CONF is not used,
nCONFIG must be pulled to VCC either directly or through a pull-up
resistor.
OE Open-Drain
Bidirectional This pin is driven low when POR is not complete. A user-selectable 2-
ms or This pin is driven low when POR is not complete. A user-
selectable 2-ms or 100-ms counter holds off the release of OE during
initial power up to permit voltage levels to stabilize. POR time can be
extended by externally holding OE low. OE is connected to the FPGA
nSTATUS signal. After the EPC device controller releases OE, it waits for
the nSTATUS-OE line to go high before starting the FPGA configuration
process. This pin contains a programmable internal weak pull-up
resistor of 6 KW that can be disabled or enabled in the Quartus II
software through the Disable nCS and OE pull-ups on configuration
device option.
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Table 9: External Flash Interface Pins
Pin Name Pin Type Description
A[20..0] Input These pins are the address input to the flash memory for read and
write operations. The addresses are internally latched during a write
cycle. When the external flash interface is not used, leave these pins
floating (with a few exceptions(4)). These flash address, data, and
control pins are internally connected to the configuration controller.
In the 100-pin PQFP package, four address pins (A0, A1, A15, A16)
are not internally connected to the controller. These loop-back
connections must be made on the board between the C-A[] and F-A[]
pins even when you are not using the external flash interface. All other
address pins are connected internal to the package. All address pins are
connected internally in the 88-pin UFBGA package. Pin A20 in EPC16
devices, pins A20 and A19 in EPC8 devices, and pins A20, A19, and
A18 in EPC4 devices are NC pins. These pins should be left floating on
the board.
DQ[15..0] Bidirectional This is the flash data bus interface between the flash memory and the
controller. The controller or an external source drives DQ[15..0]
during the flash command and the data write bus cycles. During the
data read cycle, the flash memory drives the DQ[15..0] to the
controller or external device. Leave these pins floating on the board
when the external flash interface is not used.
CE# Input Active low flash input pin that activates the flash memory when
asserted. When it is high, it deselects the device and reduces power
consumption to standby levels. This flash input pin is internally
connected to the controller. Leave this pin floating on the board when
the external flash interface is not used.
RP#(4) Input Active low flash input pin that resets the flash when asserted. When
high, it enables normal operation. When low, it inhibits write
operation to the flash memory, which provides data protection during
power transitions. This flash input is not internally connected to the
controller. Hence, an external loop-back connection between C-RP#
and F-RP# must be made on the board even when you are not using
the external flash interface. When using the external flash interface,
connect the external device to the RP# pin with the loop back. Always
tri-state RP# when the flash is not in use.
OE# Input Active-low flash-control input that is asserted by the controller or
external device during flash read cycles. When asserted, it enables the
drivers of the flash output pins. Leave this pin floating on the board
when the external flash interface is not used.
(4) These pins can be driven to 12 V during production testing of the flash memory. Since the controller
cannot tolerate the 12-V level, connections from the controller to these pins are not made internal to the
package. Instead they are available as two separate pins. You must connect the two pins at the board level
(for example, on the PCB, connect the C-WE# pin from controller to F-WE# pin from the flash memory)
.
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Pin Name Pin Type Description
WE#(4) Input Active-low flash-write strobe asserted by the controller or external
device during flash write cycles. When asserted, it controls writes to
the flash memory. In the flash memory, addresses and data are latched
on the rising edge of the WE# pulse. This flash input is not internally
connected to the controller. Hence, an external loop-back connection
between C-WE# and F-WE# must be made on the board even when
you are not using the external flash interface. When using the external
flash interface, connect the external device to the WE# pin with the
loop back.
WP# Input Usually tied to VCC or GND on the board. The controller does not
drive this pin because it could cause contention. Connection to VCC is
recommended for faster block erase or programming times and to
allow programming of the flash-bottom boot block, which is required
when programming the device using the Quartus II software. This pin
should be connected to VCC even when the external flash interface is
not used.
VCCW Supply Block erase, full-chip erase, word write, or lock-bit configuration
power supply. Connect this pin to the 3.3-V VCC supply, even when
you are not using the external flash interface.
RY/BY# Open-Drain
Output Flash asserts this pin when a write or erase operation is complete. This
pin is not connected to the controller. RY/BY# is only available in
Sharp flash-based EPC8 and EPC16.(5) Leave this pin floating when the
external flash interface is not used.
BYTE# Input Flash byte-enable pin and is only available for EPC devices in the 100-
pin PQFP package. This pin must be connected to VCC on the board
even when you are not using the external flash interface (the controller
uses the flash in 16-bit mode). For Intel flash-based EPC device, this
pin is connected to the VCCQ of the Intel flash die internally.
Therefore, BYTE# must be connected directly to VCC without using
any pull-up resistor.
Table 10: JTAG Interface Pins and Other Required Controller Pins
Pin Name Pin Type Description
TDI Input JTAG data input pin. Connect this pin to VCC if the JTAG circuitry is
not used.
TDO Output JTAG data output pin. Do not connect this pin if the JTAG circuitry is
not used (leave this pin floating).
TCK Input JTAG clock pin. Connect this pin to GND if the JTAG circuitry is not
used.
TMS Input JTAG mode select pin. Connect this pin to VCC if the JTAG circuitry
is not used.
(5) For more information, refer to the PCN0506: Addition of Intel Flash Memory As Source For EPC4,
EPC8 and EPC16 Enhanced Configuration Devices and Using the Intel Flash Memory-Based EPC4,
EPC8 and EPC16 white paper.
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Pin Name Pin Type Description
PGM[2..0] Input These three input pins select one of the eight pages of configuration
data to configure the FPGAs in the system. Connect these pins on the
board to select the page specified in the Quartus II software when
generating the EPC device POF. PGM[2] is the MSB. The default
selection is page 0;PGM[2..0]=000. These pins must not be left
floating.
EXCLK Input Optional external clock input pin that can be used to generate the
configuration clock (DCLK). When an external clock source is not used,
connect this pin to a valid logic level (high or low) to prevent a
floating-input buffer. If EXCLK is used, toggling the EXCLK input pin
after the FPGA enters user mode will not effect the EPC device
operation.
PORSEL Input This pin selects a 2-ms or 100-ms POR counter delay during power up.
When PORSEL is low, POR time is 100 ms. When PORSEL is high, POR
time is 2 ms. This pin must be connected to a valid logic level.
TM0 Input For normal operation, this test pin must be connected to GND.
TM1 Input For normal operation, this test pin must be connected to VCC.
Power-On Reset
The POR circuit keeps the system in reset until power-supply voltage levels have stabilized. The POR time
consists of the VCC ramp time and a user-programmable POR delay counter. When the supply is stable
and the POR counter expires, the POR circuit releases the OE pin. The POR time can be further extended
by an external device by driving the OE pin low.
Attention: Do not execute JTAG or ISP instructions until POR is complete.
The EPC device supports a programmable POR delay setting. You can set the POR delay to the default
100-ms setting or reduce the POR delay to 2 ms for systems that require fast power-up. The PORSEL
input pin controls this POR delay—a logic-high level selects the 2-ms delay, while a logic-low level selects
the 100-ms delay.
The EPC device enters reset under the following conditions:
The POR reset starts at initial power-up during VCC ramp-up or if VCC drops below the minimum
operating condition anytime after VCC has stabilized
The FPGA initiates reconfiguration by driving nSTATUS low, which occurs if the FPGA detects a CRC
error or if the FPGA’s nCONFIG input pin is asserted
The controller detects a configuration error and asserts OE to begin reconfiguration of the Altera
FPGA (for example, when CONF_DONE stays low after all configuration data has been transmitted)
Power Sequencing
Altera requires that you power-up the FPGA's VCCINT supply before the EPC device's POR expires.
Power up needs to be controlled so that the EPC device’s OE signal goes high after the CONF_DONE signal is
pulled low. If the EPC device exits POR before the FPGA is powered up, the CONF_DONE signal will be high
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Enhanced Configuration (EPC) Devices Datasheet Altera Corporation
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because the pull-up resistor is holding this signal high. When the EPC device exits POR, OE is released and
pulled high by a pull-up resistor. Since the EPC device samples the nCS signal on the rising edge of OE, it
detects a high level on CONF_DONE and enters an idle mode. DATA and DCLK outputs will not toggle in this
state and configuration will not begin. The EPC device will only exit this mode if it is powered down and
then powered up correctly.
Note: To ensure the EPC device enters configuration mode properly, you must ensure that the FPGA
completes power-up before the EPC device exits POR.
The pin-selectable POR time feature is useful for ensuring this power-up sequence. The EPC device has
two POR settings—2 ms when PORSEL is set to a high level and 100 ms when PORSEL is set to a low level.
For more margin, the 100-ms setting can be selected to allow the FPGA to power-up before configuration
is attempted.
Alternatively, a power-monitoring circuit or a power-good signal can be used to keep the FPGA’s
nCONFIG pin asserted low until both supplies have stabilized. This ensures the correct power up sequence
for successful configuration.
Programming and Configuration File Support
The Quartus II software provides programming support for the EPC device and automatically generates
the .pof for the EPC4, EPC8, and EPC16 devices. In a multi-device project, the Quartus II software can
combine the .sof for multiple ACEX 1K, APEX 20K, APEX II, Cyclone series, FLEX 10K, Mercury, and
Stratix series FPGAs into one programming file for the EPC device.
EPC devices can be programmed in-system through the industry-standard 4-pin JTAG interface. The ISP
feature in the EPC device provides ease in prototyping and updating FPGA functionality.
After programming an EPC device in-system, FPGA configuration can be initiated by including the EPC
device’s JTAG INIT_CONF instruction.
The ISP circuitry in the EPC device is compliant with the IEEE Std. 1532 specification. The IEEE Std. 1532
is a standard that allows concurrent ISP between devices from multiple vendors.
Table 11: JTAG Instructions for EPC Devices
Instruction register length for the EPC device is 10 and boundary scan length is 174.
JTAG Instruction OPCODE Description
SAMPLE/
PRELOAD 00 0101 0101 Allows a snapshot of the state of the EPC device pins to be
captured and examined during normal device operation and
permits an initial data pattern output at the device pins.
EXTEST 00 0000 0000 Allows the external circuitry and board-level interconnections
to be tested by forcing a test pattern at the output pins and
capturing results at the input pins.
BYPASS 11 1111 1111 Places the 1-bit bypass register between the TDI and TDO pins,
which allow the BST data to pass synchronously through a
selected device to adjacent devices during normal device
operation.
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JTAG Instruction OPCODE Description
IDCODE 00 0101 1001 Selects the device IDCODE register and places it between TDI and
TDO, allowing the device IDCODE to be serially shifted out to TDO.
The device IDCODE for all EPC devices is 0100A0DDh
USERCODE 00 0111 1001 Selects the USERCODE register and places it between TDI and
TDO, allowing the USERCODE to be serially shifted out the TDO.
The 32-bit USERCODE is a programmable user-defined pattern.
INIT_CONF 00 0110 0001 This function initiates the FPGA reconfiguration process by
pulsing the nINIT_CONF pin low, which is connected to the
FPGA nCONFIG pin. After this instruction is updated, the
nINIT_CONF pin is pulsed low when the JTAG state machine
enters Run-Test/Idle state. The nINIT_CONF pin is then released
and nCONFIG is pulled high by the resistor after the JTAG state
machine goes out of Run-Test/Idle state. The FPGA configura‐
tion starts after nCONFIG goes high. As a result, the FPGA is
configured with the new configuration data stored in flash
using ISP. This function can be added to your programming
file (.pof, .jam, and .jbc) in the Quartus II software by enabling
the Initiate configuration after programming option in the
Programmer options window (Options menu).
PENDCFG 00 0110 0101 This optional function can be used to hold the nINIT_CONF pin
low during JTAG-based ISP of the EPC device. This feature is
useful when the external flash interface is controlled by an
external FPGA or processor. This function prevents contention
on the flash pins when both the controller and external device
try to access the flash simultaneously. Before the EPC device’s
controller can access the flash memory, the external FPGA/
processor needs to tri-state its interface to flash.This can be
ensured by resetting the FPGA using the nINIT_CONF, which
drives the nCONFIG pin and keeps the external FPGA or
processor in the “reset” state. The nINIT_CONF pin is released
when the initiate configuration (INIT_CONF) JTAG instruction
is issued.
EPC devices can also be programmed by third-party flash programmers or on-board processors using the
external flash interface. Programming files (.pof) can be converted to a Hexadecimal (Intel-Format) File
(.hexout) using the Quartus II Convert Programming Files utility, for use with the programmers or
processors.
You can also program the EPC devices using the Quartus II software and the appropriate configuration
device programming adapter.
Device Package Adapter
EPC16 88-pin UFBGA PLMUEPC-88
100-pin PQFP PLMQEPC-100
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2016.05.04 Programming and Configuration File Support 25
Enhanced Configuration (EPC) Devices Datasheet Altera Corporation
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Device Package Adapter
EPC8 100-pin PQFP PLMQEPC-100
EPC4 100-pin PQFP PLMQEPC-100
Related Information
Altera Enhanced Configuration Devices
Provides more information about generating programming files.
Configuration Devices BSDL Files page
Provides more information about the EPC device JTAG support.
IEEE Std. 1149.1 (JTAG) Boundary-Scan
The EPC device provides JTAG BST circuitry that complies with the IEEE Std. 1149.1-1990 specification.
JTAG BST can be performed before or after configuration, but not during configuration.
Figure 6: JTAG Timing Waveforms
TDO
TCK
tJPZX tJPCO
tJPH
tJPXZ
tJCP tJPSU
tJCL
tJCH
TDI
TMS
Signal
to be
Captured
Signal
to be
Driven
tJSZX
tJSSU tJSH
tJSCO tJSXZ
Table 12: JTAG Timing Parameters and Values
Symbol Parameter Min Max Unit
tJCP TCK clock period 100 ns
tJCH TCK clock high time 50 ns
tJCL TCK clock low time 50 ns
tJPSU JTAG port setup time 20 ns
tJPH JTAG port hold time 45 ns
tJPCO JTAG port clock output 25 ns
26 IEEE Std. 1149.1 (JTAG) Boundary-Scan CF52002
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Symbol Parameter Min Max Unit
tJPZX JTAG port high impedance to valid output 25 ns
tJPXZ JTAG port valid output to high impedance 25 ns
tJSSU Capture register setup time 20 ns
tJSH Capture register hold time 45 ns
tJSCO Update register clock to output 25 ns
tJSZX Update register high-impedance to valid
output 25 ns
tJSXZ Update register valid output to high
impedance 25 ns
Timing Information
Figure 7: Configuration Timing Waveform Using an EPC Device
Byte0 Byte1 Byte2 Byte3 Byten
Tri-State User Mode
(2)
tOE
tPOR
tHC
tLC
tDSU
tCO
tDH
Tri-State
OE/nSTATUS
nCS/CONF_DONE
DCLK
DATA[7..0]
User I/O
INIT_DONE
nINIT_CONF or VCC/nCONFIG
Notes:
(1) The EPC device drives DCLK low after configuration.
(2) The EPC device drives DATA[] high after configuration.
Table 13: EPC Device Configuration Timing Parameters
Symbol Parameter Condition Min Typ Max Unit
fDCLK DCLK frequency 40% duty
cycle 66.7 MHz
tDCLK DCLK period 15 ns
tHC DCLK duty cycle high time 40% duty
cycle 6 ns
tLC DCLK duty cycle low time 40% duty
cycle 6 ns
tCE OE to first DCLK delay 40 ns
tOE OE to first DATA available 40 ns
CF52002
2016.05.04 Timing Information 27
Enhanced Configuration (EPC) Devices Datasheet Altera Corporation
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Symbol Parameter Condition Min Typ Max Unit
tOH DCLK rising edge to DATA change (6) ns
tCF (7) OE assert to DCLK disable delay 277 ns
tDF(7) OE assert to DATA disable delay 277 ns
tRE(8) DCLK rising edge to OE 60 ns
tLOE OE assert time to assure reset 60 ns
fECLK(9) EXCLK input frequency 40% duty
cycle 100 MHz
Operating Conditions
Table 14: Absolute Maximum Rating for EPC Devices
Symbol Parameter Condition Min Max Unit
VCC Supply voltage With respect to ground -0.2 4.6 V
VIDC input voltage With respect to ground -0.5 3.6 V
IMAX DC VCC or ground current 100 mA
IOUT DC output current, per pin -25 25 mA
PDPower dissipation 360 mW
TSTG Storage temperature No bias -65 150 C
TAMB Ambient temperature Under bias -65 135 C
TJJunction temperature Under bias 135 C
Table 15: Recommended Operating Conditions for EPC Devices
Symbol Parameter Condition Min Max Unit
VCC Supplies voltage for 3.3-
V operation 3 3.6 V
VIInput voltage With respect to ground –0.3 VCC + 0.3 V
VOOutput voltage 0 VCC V
TAOperating temperature
For commercial use 0 70 C
For industrial use –40 85 C
For military use(10) –55 125 C
(6) To calculate tOH, use the following equation: tOH = 0.5 (DCLK period) - 2.5 ns.
(7) This parameter is used for CRC error detection by the FPGA.
(8) This parameter is used for CONF_DONE error detection by the EPC device.
(9) The FPGA VCCINT ramp time should be less than 1ms for 2-ms POR and it should be less than 70 ms for
100-ms POR.
28 Operating Conditions CF52002
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Symbol Parameter Condition Min Max Unit
TRInput rise time 20 ns
TFInput fall time 20 ns
Table 16: DC Operating Conditions for EPC Devices
Symbo
lParameter Condition Min Typ Max Unit
VC
C
Supplies voltage to core 3 3.3 3.6 V
VIH High-level input voltage 2 VCC + 0.3 V
VIL Low-level input voltage 0.8 V
VO
H
3.3-V mode high-level TTL
output voltage IOH = –4 mA 2.4 V
3.3-V mode high-level CMOS
output voltage IOH = –0.1 mA VCC – 0.2 V
VO
L
Low-level output voltage TTL IOL = –4 mA DC 0.45 V
Low-level output voltage CMOS IOL = –0.1 mA DC 0.2 V
IIInput leakage current VI = VCC or ground –10 10 µA
IOZ Tri-state output off-state current VO = VCC or
ground –10 10 µA
Table 17: ICC Supply Current Values for EPC Devices
Symbol Parameter Conditio
nMin Typ Max Unit
ICC0 Current (standby) 50 150 µA
ICC1 VCC supply current (during configuration) 60 90 mA
ICCW VCCW supply current (11) (11)
Table 18: Capacitance for EPC Devices
Symbol Parameter Condition Min Max Unit
CIN Input pin capacitance 10 pF
COUT Output pin capacitance 10 pF
(10) Applicable for UBGA88 package of the EPC16 device only.
(11) For the VCCW supply current information, refer to the appropriate flash memory data sheet at
www.altera.com.
CF52002
2016.05.04 Operating Conditions 29
Enhanced Configuration (EPC) Devices Datasheet Altera Corporation
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Package
The EPC16 device is available in both the 88-pin UFBGA package and the 100-pin PQFP package. The
UFBGA package, which is based on 0.8-mm ball pitch, maximizes board space efficiency. A board can be
laid out for this package using a single PCB layer. The EPC8 and EPC4 devices are available in the 100-pin
PQFP package. EPC devices support vertical migration in the 100-pin PQFP package.
The following figure shows the PCB routing for the 88-pin UFBGA package. The Gerber file for this
layout is on the Altera website.
Figure 8: PCB Routing for 88-Pin UFBGA Package
30 Package CF52002
2016.05.04
Altera Corporation Enhanced Configuration (EPC) Devices Datasheet
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Related Information
Package and Thermal Resistance page
Provides more information about package outline drawings.
Configuration Devices Pin-Out Files
Package Layout Recommendation
Sharp flash-based EPC16 and EPC8 devices in the 100-pin PQFP packages have different package
dimensions than other Altera 100-pin PQFP devices (including the Micron flash-based EPC4 and Intel
flash-based EPC16, EPC8, and EPC4). The following figure shows the 100-pin PQFP PCB footprint
specifications for EPC devices that allows vertical migration between all devices. These footprint
dimensions are based on vendor-supplied package outline diagrams.
CF52002
2016.05.04 Package Layout Recommendation 31
Enhanced Configuration (EPC) Devices Datasheet Altera Corporation
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Figure 9: EPC Device PCB Footprint Specifications for 100-Pin PQFP Packages
Used 0.5-mm increase for front and back of nominal foot length.
Used 0.3-mm increase to maximum foot width.
2.4 mm
0.65-mm Pad Pitch
0.410 mm
0.325 mm
25.3 mm
19.3 mm
1.0 2.0
0.5 1.5 mm
Document Revision History
Date Version Changes
May 2016 2016.05.04 Removed APU support.
January 2012 3.0 Minor text edits.
June 2011 2.9 Updated Table 1–3 and Table 1–16.
32 Document Revision History CF52002
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Altera Corporation Enhanced Configuration (EPC) Devices Datasheet
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Date Version Changes
December 2009 2.8 Added Table 1–1 and Table 1–2.Updated Table 1–17 and Table
1–18.Removed “Referenced Documents” section.
October 2008 2.7 Updated Table 2–1, Table 2–7, and Table 2–8.Updated Figure
2–2, Figure 2–3, and Figure 2–4.Updated “JTAG-based
Programming”section. Added“Intel-Flash-Based EPC Device
Protection” section. Updatednew document format.
May 2008 2.6 Minor textual and style changes. Added “Referenced
Documents” section.
February 2008 2.5 Updated Table 2–18 with information about EPC16UI88AA.
May 2007 2.4 Added“Intel-Flash-Based EPC Device Protection” section.
April 2007 2.3 Added document revision history.
October 2005 2.2 Made changes to content.
July 2004 2.0 AddedStratix IIandCyclone II device information throughout
chapter. Updated VCCW connection inFigure2–2, Figure 2–3,
and Figure 2–4.Updated (Note 2) of Figure2–2, Figure 2–3, and
Figure 2–4. Updated (Note 4) of Table2–12.Updatedunit
ofICC0in Table2–16.AddedICCW toTable2–16.
September 2003 1.0 Initial Release.
CF52002
2016.05.04 Document Revision History 33
Enhanced Configuration (EPC) Devices Datasheet Altera Corporation
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