January 2012 Altera Corporation
CF52005-3.0 Datasheet
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ISO
9001:2008
Registered
Configuration Devices for SRAM-Based
LUT Devices
This datasheet describes configuration devices for SRAM-based look-up table (LUT)
devices.
Supported Devices
Tabl e 1 lists the supported Altera configuration devices.
Features
Configuration devices for SRAM-based LUT devices offer the following features:
Configures Altera ACEX1K, APEX20K (including APEX 20K, APEX 20KC, and
APEX 20KE), APEX II, ArriaGX, Cyclone, Cyclone II, FLEX10K (including
FLEX 10KE and FLEX 10KA) Mercury, Stratix, Stratix GX, Stratix II, and
Stratix II GX devices
Easy-to-use four-pin interface
Low current during configuration and near-zero standby mode current
Programming support with the Altera Programming Unit (APU) and
programming hardware from Data I/O, BP Microsystems, and other third-party
programmers
Available in compact plastic packages
8-pin plastic dual in-line (PDIP) package
20-pin plastic J-lead chip carrier (PLCC) package
32-pin plastic thin quad flat pack (TQFP) package
EPC2 device has reprogrammable flash configuration memory
Table 1. Altera Configuration Devices
Device Memory Size (Bits) ISP Support Cascaded
Support Reprogrammable Recommended
Operating Voltage (V)
EPC1 1,046,496 No Yes No 5.0 or 3.3
EPC2 1,695,680 Yes Yes Yes 5.0 or 3.3
EPC1064 65,536 No No No 5.0
EPC1064V 65,536 No No No 3.3
EPC1213 212,942 No Yes No 5.0
EPC1441 440,800 No No No 5.0 or 3.3
Page 2 Functional Description
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
5.0-V and 3.3-V in-system programmability (ISP) through the built-in IEEE Std.
1149.1 JTAG interface
Built-in JTAG boundary-scan test (BST) circuitry compliant with IEEE Std. 1149.1
Supports programming through Serial Vector Format File (.svf), Jam Standard
Test and Programming Language (STAPL) Format File (.jam), JAM Byte Code File
(.jbc), and the QuartusII and MAX+PLUSII softwares using the USB-Blaster,
MasterBlaster, ByteBlasterII, EthernetBlaster, or ByteBlasterMV download
cable
Supports programming through Programmer Object File (.pof) for EPC1 and
EPC1441 devices
nINIT
_
CONF
pin allows
INIT
_
CONF
JTAG instruction to begin FPGA configuration
fFor more information about enhanced configuration (EPC) devices, refer to the
Enhanced Configuration (EPC) Devices Datasheet.
fFor more information about serial configuration (EPCS) devices, refer to the Serial
Configuration (EPCS) Devices Datasheet.
Functional Description
With SRAM-based devices, configuration data must be reloaded each time the device
powers up, the system initializes, or when new configuration data is needed. Altera
configuration devices store configuration data for SRAM-based ACEX 1K, APEX 20K,
APEX II, Arria GX, Cyclone, Cyclone II, FLEX 10K, FLEX 6000, Mercury, Stratix,
Stratix GX, Stratix II, and Stratix II GX devices.
Tabl e 2 lists the supported configuration devices required to configure the ACEX 1K,
APEX 20K, APEX 20KC, APEX 20KE, APEX II, Cyclone, Cyclone II, FLEX 10K,
FLEX 10KA, FLEX 10KE, FLEX 6000/A, FLEX 8000A, Mercury, Stratix, Stratix GX, or
Stratix II device.
Table 2. Supported Configuration Devices (Part 1 of 4)
Device Family Device Data Size (Bits)
(1)
EPC1064 or
EPC1064V EPC1213 EPC1441 EPC1 EPC2
ACEX 1K
EP1K10 159,160 1 1 1
EP1K30 473,720 1 1
EP1K50 784,184 1 1
EP1K100 1,335,720 1
APEX 20K
EP20K100 993,360 1 1
EP20K200 1,950,800 2
EP20K400 3,880,720 3
APEX 20KC
EP20K200C 1,968,016 2
EP20K400C 3,909,776 3
EP20K600C 5,673,936 4
EP20K1000C 8,960,016 6
Functional Description Page 3
Configuration Devices for SRAM-Based LUT DevicesJanuary 2012 Altera Corporation
APEX 20KE
EP20K30E 354,832 1 1 1
EP20K60E 648,016 1 1
EP20K100E 1,008,016 1 1
EP20K160E 1,524,016 1
EP20K200E 1,968,016 2
EP20K300E 2,741,616 2
EP20K400E 3,909,776 3
EP20K600E 5,673,936 4
EP20K1000E 8,960,016 6
EP20K1500E 12,042,256 8
APEX II
EP2A15 1,168,688 3
EP2A25 1,646,544 4
EP2A40 2,543,016 6
EP2A70 4,483,064 ———11
Cyclone
EP1C3 627,376 1 1
EP1C4 925,000 1 1
EP1C6 1,167,216 1 (2) 1
EP1C12 2,326,528 1 (2)
EP1C20 3,559,608 2 (2)
Cyclone II
EP2C5 1,265,792 1
EP2C8 1,983,536 2
EP2C20 3,892,496 3
EP2C35 6,848,608 5
EP2C50 9,951,104 6
EP2C70 14,319,216 9
FLEX 10K
EPF10K10 118,000 1 1 1
EPF10K20 231,000 1 1 1
EPF10K30 376,000 1 1 1
EPF10K40 498,000 1 1
EPF10K50 621,000 1 1
EPF10K70 892,000 1 1
EPF10K100 1,200,000 1
FLEX 10KA
EPF10K10A 120,000 1 1 1
EPF10K30A 406,000 1 1 1
EPF10K50V 621,000 1 1
EPF10K100A 1,200,000 1
EPF10K130V 1,600,000 1
EPF10K250A 3,300,000 2
Table 2. Supported Configuration Devices (Part 2 of 4)
Device Family Device Data Size (Bits)
(1)
EPC1064 or
EPC1064V EPC1213 EPC1441 EPC1 EPC2
Page 4 Functional Description
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
FLEX 10KE
EPF10K30E 473,720 1 1
EPF10K50E 784,184 1 1
EPF10K50S 784,184 1 1
EPF10K100B 1,200,000 1
EPF10K100E 1,335,720 1
EPF10K130E 1,838,360 2
EPF10K200E 2,756,296 2
EPF10K200S 2,756,296 2
FLEX 6000/A
EPF6010A 260,000 1 1
EPF6016(5.0 V)/
EPF6016A 260,000 1 1
EPF6024A 398,000 1 1
FLEX 8000A
EPF8282A /
EPF8282AV(3.3 V) 40,000 1 1 1 1
EPF8452A 64,000 1 1 1 1
EPF8636A 96,000 1 1 1
EPF8820A 128,000 1 1 1
EPF81188A 192,000 1 1 1
EPF81500A 250,000 1 1
Mercury EP1M120 1,303,120 1
EP1M350 4,394,032 3
Stratix
EP1S10 3,534,640 3 (3)
EP1S20 5,904,832 4
EP1S25 7,894,144 5
EP1S30 10,379,368 7
EP1S40 12,389,632 8
EP1S60 17,543,968 ———11
EP1S80 23,834,032 ———15
Stratix GX
EP1SGX10 3,534,640 3
EP1SGX25 7,894,144 5
EP1SGX40 12,389,632 8
Table 2. Supported Configuration Devices (Part 3 of 4)
Device Family Device Data Size (Bits)
(1)
EPC1064 or
EPC1064V EPC1213 EPC1441 EPC1 EPC2
Functional Description Page 5
Configuration Devices for SRAM-Based LUT DevicesJanuary 2012 Altera Corporation
Figure 1 shows the configuration device block diagram.
Stratix II
EP2S15 5,000,000 3
EP2S30 10,100,000 7
EP2S60 17,100,000 ———11
EP2S90 27,500,000 ———17
EP2S130 39,600,000 ———24
EP2S180 52,400,000 ———31
Notes to Table 2:
(1) Raw Binary File (.rbf) were used to determine these sizes.
(2) This number is calculated with the Cyclone series compression feature enabled.
(3) EP1S10 ES devices requires four EPC2 devices.
Table 2. Supported Configuration Devices (Part 4 of 4)
Device Family Device Data Size (Bits)
(1)
EPC1064 or
EPC1064V EPC1213 EPC1441 EPC1 EPC2
Figure 1. Configuration Device Block Diagram
Notes to Figure 1:
(1) The EPC1441 devices do not support data cascading. The EPC1, EPC2, and EPC1213 devices support data cascading.
(2) The
OE
pin is a bidirectional open-drain pin.
DCLK
nCS
OE
Decode
Logic
Address
DATA
DATA
Shift
Register
EPROM
Array
nCS
Decode
Logic
Address
Oscillator
Oscillator
Control
EPROM
Array
Shift
Register
DATA
DATA
DCLK
nCASC
nCASC
(1)
(1)
FPGA (except FLEX 8000) Configuration Using an EPC2, EPC1, or EPC1441
FLEX 8000 Device Configuration Using an EPC1, EPC1441, EPC1213, EPC1064, or EPC1064V
Address
Counter
CLK
ENA
nRESET
Error
Detection
Circuitry
OE
Address
Counter
CLK
ENA
nRESET
(2)
Page 6 Device Configuration
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
Device Configuration
The EPC1, EPC2, and EPC1441 devices store configuration data in its erasable
programmable read-only memory (EPROM) array and serially clock data out using
an internal oscillator. The
OE
,
nCS
, and
DCLK
pins supply the control signals for the
address counter and the
DATA
output tri-state buffer. The configuration device sends a
serial bitstream of configuration data to its
DATA
pin, which is routed to the
DATA0
input of the FPGA.
The control signals for configuration devices,
OE
,
nCS
, and
DCLK
, interface directly with
the FPGA control signals,
nSTATUS
,
CONF
_
DONE
, and
DCLK
. All Altera FPGAs can be
configured by a configuration device without requiring an external intelligent
controller.
1An EPC2 device cannot configure FLEX 8000 or FLEX 6000 devices. For configuration
devices that support FLEX 8000 or FLEX 6000 devices, refer to Table 2.
Figure 2 shows the basic configuration interface connections between the
configuration device and the Altera FPGA.
The EPC2 device allows you to begin configuration of the FPGA using an additional
pin,
nINIT
_
CONF
. The
nINIT
_
CONF
pin of the EPC2 device can be connected to the
nCONFIG
pin of the FPGA, which allows the
INIT
_
CONF
JTAG instruction to begin
FPGA configuration. The
INIT
_
CONF
JTAG instruction causes the EPC2 device to drive
the
nINIT
_
CONF
pin low, which in turn pulls the
nCONFIG
pin low. Pulling the
nCONFIG
pin low on the FPGA will reset the device. When the JTAG state machine exits this
state, the
nINIT
_
CONF
pin is released and pulled high by an internal 1-k resistor,
which in turn pulls the
nCONFIG
pin high to begin configuration. If you do not use the
nINIT
_
CONF
pin, disconnect the
nINIT
_
CONF
pin, and pull the
nCONFIG
pin of the FPGA
to VCC either directly or through a resistor.
Figure 2. Altera FPGA Configured Using an EPC1, EPC2, or EPC1441 Configuration Device (1)
Notes to Figure 2:
(1) For more information about configuration interface connections, refer to the configuration chapter in the appropriate device handbook.
(2) The n
INIT
_
CONF
pin which is available on EPC2 devices has an internal pull-up resistor that is always active. This means an external pull-up
resistor is not required on the n
INIT
_
CONF
/n
CONFIG
line. The n
INIT
_
CONF
pin does not need to be connected if its functionality is not used.
If the n
INIT
_
CONF
pin is not used or unavailable, n
CONFIG
must be pulled to VCC
either directly or through a resistor.
(3) EPC2 devices have internal programmable pull-up resistors on
OE
and n
CS
pins. If internal pull-up resistors are used, do not use external pull-up
resistors on these pins. The internal pull-up resistors are set 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 you generate programming files.
FPGA
Configuration
Device
DCLK
DATA
OE (3)
nCS (3)
nINIT_CONF (2)
MSEL
DCLK
DATA0
nSTATUS
CONF_DONE
nCONFIG
VCC VCC
GND
nCE
VCC
nCEO
nCASC N.C.
N.C.
n
(2)(3) (3)
Device Configuration Page 7
Configuration Devices for SRAM-Based LUT DevicesJanuary 2012 Altera Corporation
The EPC2 device’s
OE
and
nCS
pins have internal programmable pull-up resistors. If
you use internal pull-up resistors, do not use external pull-up resistors on these pins.
The internal pull-up resistors are set 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 you generate programming files.
The configuration device’s
OE
and
nCS
pins control the tri-state buffer on its
DATA
output pin and enable the address counter and oscillator. When the
OE
pin is driven
low, the configuration device resets the address counter and tri-states its
DATA
pin. The
nCS
pin controls the
DATA
output of the configuration device. If the
nCS
pin is held high
after the
OE
reset pulse, the counter is disabled and the
DATA
output pin is tri-stated. If
the
nCS
pin is driven low after the
OE
reset pulse, the counter and
DATA
output pin are
enabled. When
OE
is driven low again, the address counter is reset and the
DATA
output pin is tri-stated, regardless of the state of the
nCS
pin.
If the FPGAs configuration data exceeds the capacity of a single EPC1 or EPC2
configuration device, you can cascade multiple EPC1 or EPC2 devices together. If
multiple EPC1 or EPC2 devices are required, the
nCASC
and
nCS
pins provide
handshaking between the configuration devices.
1EPC1441 and EPC1064/EPC1064V devices cannot be cascaded.
When configuring ACEX 1K, APEX 20K, APEX II, Arria GX, Cyclone, Cyclone II,
FLEX 10K, Mercury, Stratix, Stratix GX, Stratix II, and Stratix II GX devices with
cascaded EPC1 or EPC2 devices, the position of the EPC1 or EPC2 device in the chain
determines its mode of operation. The first configuration device in the chain is the
master, while subsequent configuration devices are slaves. The
nINIT
_
CONF
pin of the
EPC2 master device can be connected to the
nCONFIG
pin of the FPGAs, which allows
the
INIT
_
CONF
JTAG instruction to begin FPGA configuration. The
nCS
pin of the
master configuration device is connected to the
CONF
_
DONE
pin of the FPGAs, while its
nCASC
pin is connected to the
nCS
pin of the next slave configuration device in the
chain. Additional EPC1 or EPC2 devices can be chained together by connecting the
nCASC
pin to the
nCS
pin of the next EPC1 or EPC2 slave device in the chain. The last
device’s
nCS
input comes from the previous device, while its
nCASC
pin is left floating.
All other configuration pins,
DCLK
,
DATA
, and
OE
, are connected to every device in the
chain.
fFor more information about configuration interface connections, including pull-up
resistor values, supply voltages, and
MSEL
pin setting, refer to the configuration
chapter in the appropriate device handbook.
Page 8 Device Configuration
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
Figure 3 shows the basic configuration interface connections between a configuration
device chain and the Altera FPGA.
When the first device in a configuration device chain is powered-up or reset, its
nCS
pin is driven low because it is connected to the
CONF
_
DONE
pin of the FPGA. Because
both
OE
and
nCS
pins are low, the first device in the chain recognizes it as the master
device and controls configuration. Since the slave devices
nCS
pin is fed by the
previous devices’
nCASC
pin, its
nCS
pin is high after power-up and reset. In the slave
configuration devices, the
DATA
output is tri-stated and
DCLK
is an input. During
configuration, the master device supplies the clock through
DCLK
to the FPGA and to
any slave configuration devices. The EPC1 or EPC2 master device also provides the
first stream of data to the FPGA during multi-device configuration. After the EPC1 or
EPC2 master device finishes sending configuration data, it tri-states its
DATA
pin to
avoid contention with other configuration devices. The EPC1 or EPC2 master device
also drives its
nCASC
pin low, which pulls the
nCS
pin of the next device low. This
action signals the EPC1 or EPC2 slave device to start sending configuration data to the
FPGAs.
The EPC1 or EPC2 master device clocks all slave configuration devices until
configuration is complete. When all configuration data is transferred and the
nCS
pin
on the EPC1 or EPC2 master device is driven high by the FPGAs
CONF
_
DONE
pin, the
EPC1 or EPC2 master device then goes into zero-power (idle) state. The EPC2 master
device drives
DATA
high and
DCLK
low, while the EPC1 and EPC1441 device tri-state
DATA
and drive
DCLK
low.
If the
nCS
pin on the EPC1 or EPC2 master device is driven high before all
configuration data is transferred, the EPC1 or EPC2 master device drives its
OE
signal
low, which in turn drives the FPGAs
nSTATUS
pin low, indicating a configuration
error. Additionally, if the configuration device generates its data and detects that the
CONF
_
DONE
pin has not gone high, it recognizes that the FPGA has not configured
successfully. EPC1 and EPC2 devices wait for 16
DCLK
cycles after the last
Figure 3. Altera FPGA Configured Using Two EPC1 or EPC2 Configuration Devices (1)
Notes to Figure 3:
(1) For more information about configuration interface connections, refer to the configuration chapter in the appropriate device handbook.
(2) The n
INIT
_
CONF
pin which is available on EPC2 devices has an internal pull-up resistor that is always active. This means an external pull-up
resistor is not required on the n
INIT
_
CONF
/n
CONFIG
line. The n
INIT
_
CONF
pin does not need to be connected if its functionality is not used.
If the n
INIT
_
CONF
pin is not used or unavailable, n
CONFIG
must be pulled to VCC
either directly or through a resistor.
(3) EPC2 devices have internal programmable pull-up resistors on
OE
and n
CS
pins. If internal pull-up resistors are used, do not use external pull-up
resistors on these pins. The internal pull-up resistors are set 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 you generate programming files.
VCC VCC
GND
DCLK
DATA
nCS
OE
FPGA
MSEL
DCLK
DATA0
nSTATUS
CONF_DONE
nCONFIG
nCE
Master
Configuration
Device
Slave
Configuration
Device
DCLK
DATA
OE (3)
nCS (3)
nINIT_CONF
(2)
nCASC nCASC N.C.
nCEO N.C.
VCC
(2)(3) (3)
n
Power and Operation Page 9
Configuration Devices for SRAM-Based LUT DevicesJanuary 2012 Altera Corporation
configuration bit was sent for the
CONF
_
DONE
pin to reach a high state. In this case, the
configuration device pulls its
OE
pin low, which in turn drives the target device’s
nSTATUS
pin low. Configuration automatically restarts if the Auto-restart
configuration on error option is turned on in the Quartus II software from the
General tab of the Device & Pin Options dialog box or the MAX+PLUS II software’s
Global Project Device Options dialog box (Assign menu).
fFor more information about FPGA configuration and configuration interface
connections between configuration devices and Altera FPGAs, refer to the
configuration chapter in the appropriate device handbook.
Power and Operation
This section describes power-on reset (POR) delay, error detection, and 3.3-V and
5.0-V operation of Altera configuration devices.
Power-On Reset
During initial power-up, a POR delay occurs to permit voltage levels to stabilize.
When configuring an FPGA with one EPC1, EPC2, or EPC1441 device, the POR delay
occurs inside the configuration device and the POR delay is a maximum of 200 ms.
When configuring a FLEX 8000 device with one EPC1213, EPC1064, or EPC1064V
device, the POR delay occurs inside the FLEX 8000 device and the POR delay is
typically 100 ms, with a maximum of 200 ms.
During POR, the configuration device drives its
OE
pin low. This low signal delays
configuration because the
OE
pin is connected to the target FPGAs
nSTATUS
pin. When
the configuration device completes POR, it releases its open-drain
OE
pin, which is
then pulled high by a pull-up resistor.
1You should power up the FPGA before the configuration device exits POR to avoid
the master configuration device from entering slave mode.
If the FPGA is not powered up before the configuration device exits POR, the
CONF
_
DONE
/
nCS
line is high because of the pull-up resistor. When the configuration
device exits POR and releases
OE
, it sees
nCS
high, which signals the configuration
device to enter slave mode. Therefore, configuration will not begin because the
DATA
output is tri-stated and
DCLK
is an input pin in slave mode.
Error Detection Circuitry
The EPC1, EPC2, and EPC1441 configuration devices have built-in error detection
circuitry for configuring ACEX 1K, APEX 20K, APEX II, Arria GX, Cyclone,
Cyclone II, FLEX 10K, FLEX 6000, Mercury, Stratix, Stratix GX, Stratix II, or
Stratix II GX devices.
Built-in error detection circuitry uses the
nCS
pin of the configuration device, which
monitors the
CONF
_
DONE
pin on the FPGA. If the
nCS
pin on the EPC1 or EPC2 master
device is driven high before all configuration data is transferred, the EPC1 or EPC2
master device drives its
OE
signal low, which in turn drives the FPGA’s
nSTATUS
pin
low, indicating a configuration error. Additionally, if the configuration device
generates its data and detects that the
CONF
_
DONE
pin has not gone high, it recognizes
Page 10 Power and Operation
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
that the FPGA has not configured successfully. EPC1 and EPC2 devices wait for
16
DCLK
cycles after the last configuration bit was sent for the
CONF
_
DONE
pin to reach a
high state. In this case, the configuration device pulls its
OE
pin low, which in turn
drives the target device’s
nSTATUS
pin low. Configuration automatically restarts if the
Auto-restart configuration on error option is turned on in the Quartus II software
from the General tab of the Device & Pin Options dialog box or the MAX+PLUS II
software’s Global Project Device Options dialog box (Assign menu).
In addition, if the FPGA detects a cyclic redundancy check (CRC) error in the received
data, it will flag the error by driving the
nSTATUS
signal low. This low signal on
nSTATUS
drives the
OE
pin of the configuration device low, which resets the
configuration device. CRC checking is performed when configuring all Altera FPGAs.
3.3-V or 5.0-V Operation
Power the EPC1, EPC2, and EPC 1441 configuration device at 3.3 V or 5.0 V. For each
configuration device, an option must be set for the 3.3-V or 5.0-V operation.
For EPC1 and EPC1441 configuration devices, 3.3-V or 5.0-V operation is controlled
by a programming bit in the .pof. The Low-Voltage mode option in the Options tab of
the Configuration Device Options dialog box in the Quartus II software or the Use
Low-Voltage Configuration EPROM option in the Global Project Device Options
dialog box (Assign menu) in the MAX+PLUS II software sets this parameter. For
example, EPC1 devices are programmed automatically to operate in 3.3-V mode when
configuring FLEX 10KA devices, which have a VCC voltage of 3.3 V. In this example,
the EPC1 device’s
VCC
pin is connected to a 3.3-V power supply.
For EPC2 devices, this option is set externally by the
VCCSEL
pin. In addition, the EPC2
device has an externally controlled option, set by the
VPPSEL
pin, to adjust the
programming voltage to 5.0 V or 3.3 V. The functions of the
VCCSEL
and
VPPSEL
pins
are described below. These pins are only available in the EPC2 devices.
VCCSEL
pin—For EPC2 configuration devices, 5.0-V or 3.3-V operation is controlled
by the
VCCSEL
option pin. The device functions in 5.0-V mode when
VCCSEL
is
connected to GND and 3.3-V mode when
VCCSEL
is connected to VCC.
VPPSEL
pin—The VPP programming power pin of the EPC2 device is normally tied
to VCC. For EPC2 devices operating at 3.3 V, it is possible to improve ISP time by
setting VPP to 5.0 V. For all other configuration devices, VPP must be tied to VCC.
The
VPPSEL
pin of the EPC2 device must be set in accordance with the
VPP
pin of
the EPC2 device. If the
VPP
pin is supplied by a 5.0-V power supply,
VPPSEL
must
be connected to GND and if the
VPP
pin is supplied by a 3.3-V power supply,
VPPSEL
must be connected to VCC.
Power and Operation Page 11
Configuration Devices for SRAM-Based LUT DevicesJanuary 2012 Altera Corporation
Tabl e 3 lists the relationship between the VCC and VPP voltage levels and the required
logic level for
VCCSEL
and
VPPSEL
pins. A high logic level means the pin should be
connected to VCC, while a low logic level means the pin should be connected to GND.
At a 3.3-V operation, all EPC2 inputs are 5.0-V tolerant, except for
DATA
,
DCLK
, and
nCASC
pins. The
DATA
and
DCLK
pins are used only to interface between the EPC2
device and the FPGA it is configuring. Tab l e 4 lists the voltage tolerences of all EPC2
device pins.
If one EPC1, EPC2, or EPC1441 configuration device is powered at 3.3 V, the
nSTATUS
and
CONF
_
DONE
pull-up resistors must be connected to 3.3 V. If these configuration
devices are powered at 5.0 V, the
nSTATUS
and
CONF
_
DONE
pull-up resistors can be
connected to either 3.3 V or 5.0 V.
Table 3. VCCSEL and VPPSEL Pin Functions on the EPC2 Device
VCC Voltage Level
(V)
VPP Voltage Level
(V)
VCCSEL Pin Logic
Level
VPPSEL Pin Logic
Level
3.3 3.3 High High
3.3 5.0 High Low
5.0 5.0 Low Low
Table 4. EPC2 Device Input and Bidirectional Pin Voltage Tolerance
Pin
5.0-V Operation 3.3-V Operation
5.0-V Tolerant 3.3-V Tolerant 5.0-V Tolerant 3.3-V Tolerant
DATA
vvv
DCLK
vvv
n
CASC
vvv
OE
vvvv
n
CS
vvvv
VCCSEL
vvvv
VPPSEL
vvvv
n
INIT_CONF
vvvv
TDI
vvvv
TMS
vvvv
TCK
vvvv
Page 12 Programming and Configuration File Support
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
Programming and Configuration File Support
The Quartus II and MAX+PLUS II softwares provide programming support for Altera
configuration devices. During compilation, the Quartus II and MAX+PLUS II
softwares automatically generates a .pof, which is used to program the configuration
devices. In a multi-device configuration, the software combines the programming
files for multiple ACEX 1K, APEX 20K, APEX II, Arria GX, Cyclone, Cyclone II,
FLEX 10K, Mercury, Stratix, Stratix GX, Stratix II, and Stratix II GX devices into one or
more configuration devices. The software allows you to select the appropriate
configuration device to store the data for each FPGA.
All Altera configuration devices are programmable using Altera programming
hardware in conjunction with the Quartus II or MAX+PLUS II software. In addition,
many third-party programmers offer programming hardware that supports Altera
configuration devices.
1An EPC2 device can be programmed with a .pof generated for an EPC1 or EPC1441
device. An EPC1 device can be programmed with a .pof generated for an EPC1441
device.
EPC2 configuration devices can be programmed in-system through its
industry-standard four-pin JTAG interface. ISP capability in the EPC2 devices provide
ease in prototyping and FPGA functionality. When programming multiple EPC2
devices in a JTAG chain, the Quartus II and MAX+PLUS II softwares and other
programming methods employ concurrent programming to simultaneously program
multiple devices and reduce programming time. EPC2 devices can be programmed
and erased up to 100 times.
After programming an EPC2 device in-system, FPGA configuration is initiated by the
INIT
_
CONF
JTAG instruction of the EPC2 device. For more information, refer to
Tabl e 6.
fFor more information about programming and configuration support, refer to the
following documents:
Altera Programming Hardware Data Sheet
USB-Blaster Download Cable User Guide
MasterBlaster Serial/USB Communications Cable User Guide
ByteBlaster II Download Cable User Guide
ByteBlasterMV Download Cable User Guide
BitBlaster Serial Download Cable Data Sheet
You can also program the configuration devices using the Quartus II or MAX+PLUS II
software with the APU or the appropriate configuration device programming adapter.
Programming and Configuration File Support Page 13
Configuration Devices for SRAM-Based LUT DevicesJanuary 2012 Altera Corporation
Tabl e 5 lists the programming adapter to use with each configuration device.
To program Altera configuration devices using the Quartus II software and the APU,
follow these steps:
1. Choose the Quartus II Programmer (Tools menu).
2. Load the appropriate .pof by clicking Add. The Device column displays the
device for the current programming file.
3. Insert a blank configuration device into the programming adapters socket.
4. Turn on the Program/Configure. You can also turn on Verify to verify the contents
of a programmed device against the programming data loaded from a
programming file.
5. Click Start.
6. After successful programming, you can place the configuration device on the PCB
to configure the FPGA device.
To program Altera configuration devices using the MAX+PLUS II software and the
APU, follow these steps:
1. Open the MAX+PLUS II Programmer.
2. Load the appropriate .pof using the Select Programming File dialog box (File
menu). By default, the Programmer loads the current project’s .pof. The Device
field displays the device for the current programming file.
3. Insert a blank configuration device into the programming adapters socket.
4. Click Program.
5. After successful programming, you can place the configuration device on the PCB
to configure the FPGA device.
If you are cascading EPC1 or EPC2 devices, you must generate multiple .pof. The first
device .pof have the same name as the project, while the second device .pof have the
same name as the first, but with a “_1” extension (e.g., top_1.pof).
Table 5. Programming Adapters
Device Package Adapter
EPC2 20-pin J-Lead PLMJ1213
32-pin TQFP PLMT1213
EPC1 8-pin DIP PLMJ1213
20-pin J-Lead PLMJ1213
EPC1441
8-pin DIP PLMJ1213
20-pin J-Lead PLMJ1213
32-pin TQFP PLMT1064
Page 14 IEEE Std. 1149.1 (JTAG) Boundary-Scan Testing
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
IEEE Std. 1149.1 (JTAG) Boundary-Scan Testing
The EPC2 device provides JTAG BST circuitry that complies with the IEEE Std.
1149.1-1990 specification. You can perform JTAG BST before or after configuration, but
not during configuration. Table 6 lists the JTAG instructions supported by the EPC2
device.
fFor more information, refer to AN39: IEEE 1149.1 JTAG Boundary-Scan Testing in Altera
Devices.
Table 6. EPC2 Device JTAG Instructions
JTAG Instruction OPCODE Description
SAMPLE/PRELOAD 00 0101 0101
Allows a snapshot of a signal at the 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 allows the BST data to pass synchronously through a selected
device to adjacent devices during normal device operation.
IDCODE 00 0101 1001
Selects the device
IDCODE
register and places it between the
TDI
and
TDO
pins, allowing the device
IDCODE
to be serially shifted out of
the
TDO
pin. The device
IDCODE
for the EPC2 configuration device is
shown below:
0000 0001000000000010 00001101110 1
USERCODE 00 0111 1001
Selects the USERCODE register and places it between the
TDI
and
TDO
pins, allowing the USERCODE to be serially shifted out of the
TDO
pin. The 32-bit USERCODE is a programmable user-defined
pattern.
INIT_CONF 00 0110 0001
Initiates the FPGA re-configuration process by pulsing the
n
INIT_CONF
pin low, which is connected to the FPGAs n
CONFIG
pins. After this instruction is updated, the n
INIT_CONF
pin is pulsed
low when the JTAG state machine enters the Run-Test/Idle state. The
n
INIT_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 configuration starts after the n
CONFIG
pin goes high. As a
result, the FPGA is configured with the new configuration data stored
in the configuration device. You can add this function to your
programming file (.pof, .jam, .jbc) in the Quartus II software by
enabling the Initiate configuration after programming option in the
Programmer options window (Options menu). This instruction is
also used by the MAX+PLUS II software, .jam files, and .jbc files.
ISP Instructions
These instructions are used when programming an EPC2 device
using JTAG ports with a USB-Blaster, MasterBlaster, ByteBlaster II,
EthernetBlaster, or ByteBlasterMV download cable, or using a .jam,
.jbc, or .svf file using an embedded processor.
IEEE Std. 1149.1 (JTAG) Boundary-Scan Testing Page 15
Configuration Devices for SRAM-Based LUT DevicesJanuary 2012 Altera Corporation
Figure 4 shows the timing requirements for the JTAG signals.
Tabl e 7 lists the timing parameters and values for configuration devices.
Figure 4. EPC2 Device JTAG Waveforms
Table 7. JTAG Timing Parameters and Values
Symbol Parameter Min Max Unit
t
JCP
TCK
clock period 100 ns
t
JCH
TCK
clock high time 50 ns
t
JCL
TCK
clock low time 50 ns
t
JPSU JTAG port setup time 20 ns
t
JPH JTAG port hold time 45 ns
t
JPCO JTAG port clock to output 25 ns
t
JPZX JTAG port high impedance to valid output 25 ns
t
JPXZ JTAG port valid output to high impedance 25 ns
t
JSSU Capture register setup time 20 ns
t
JSH Capture register hold time 45 ns
t
JSCO Update register clock to output 25 ns
t
JSZX Update register high impedance to valid output 25 ns
t
JSXZ Update register valid output to high impedance 25 ns
TDO
TCK
t
JPZX tJPCO
tJPH
tJPXZ
tJCP
tJPSU
tJCL
tJCH
TDI
TMS
Signal
to be
Captured
Signal
to be
Driven
tJSZX
tJSSU tJSH
tJSCO tJSXZ
Page 16 Timing Information
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
Timing Information
Figure 5 shows the timing waveform when using a configuration device.
Tabl e 8 lists the timing parameters when using EPC2 devices at 3.3 V.
Figure 5. Timing Waveform Using a Configuration Device
Note to Figure 5:
(1) The EPC2 device drives DCLK low and DATA high after configuration. The EPC1 and EPC1441 devices drive DCLK low and tri-state DATA after
configuration.
DDDD
0123Dn
Tr i - S t a t e User Mode
(1)
tOEZX
tPOR
tCH
tCL
tDSU
tCO
tDH
Tr i - S t a t e
OE/nSTATUS
nCS/CONF_DONE
DCLK
DATA
User I/O
INIT_DONE
nINIT_CONF or VCC/nCONFIG
Table 8. Timing Parameters when Using EPC2 devices at 3.3 V
Symbol Parameter Min Typ Max Units
tPOR POR delay (1) ——200ms
tOEZX
OE
high to
DATA
output enabled 80 ns
tCE
OE
high to first rising edge on
DCLK
——300ns
tDSU
Data
setup time before rising edge on
DCLK
30 ns
tDH
Data
hold time after rising edge on
DCLK
0—ns
tCO
DCLK
to
DATA
out 30 ns
tCDOE
DCLK
to
DATA
enable/disable 30 ns
fCLK
DCLK
frequency 5 7.7 12.5 MHz
tMCH
DCLK
high time for the first device in the configuration chain 40 65 100 ns
tMCL
DCLK
low time for the first device in the configuration chain 40 65 100 ns
tSCH
DCLK
high time for subsequent devices 40 ns
tSCL
DCLK
low time for subsequent devices 40 ns
tCASC
DCLK
rising edge to n
CASC
25 ns
tCCA n
CS
to
nCASC
cascade delay 15 ns
tOEW
OE
low pulse width (reset) to guarantee counter reset 100 ns
tOEC
OE
low (reset) to
DCLK
disable delay 30 ns
tNRCAS
OE
low (reset) to n
CASC
delay 30 ns
Note to Tabl e 8:
(1) During initial power-up, a POR delay occurs to permit voltage levels to stabilize. Subsequent reconfigurations do not incur this delay.
Timing Information Page 17
Configuration Devices for SRAM-Based LUT DevicesJanuary 2012 Altera Corporation
Tabl e 9 lists the timing parameters when using EPC1 and EPC1441 devices at 3.3 V.
Tabl e 10 lists the timing parameters when using EPC1, EPC2, and EPC1441 devices at
5.0 V.
Table 9. Timing Parameters when Using EPC1 and EPC1441 Devices at 3.3 V
Symbol Parameter Min Typ Max Units
tPOR POR delay (1) ——200ms
tOEZX
OE
high to
DATA
output enabled 80 ns
tCE
OE
high to first rising edge on
DCLK
——300ns
tDSU
Data
setup time before rising edge on
DCLK
30 ns
tDH
Data
hold time after rising edge on
DCLK
0—ns
tCO
DCLK
to
DATA
out 30 ns
tCDOE
DCLK
to
DATA
enable/disable 30 ns
fCLK
DCLK
frequency 2 4 10 MHz
tMCH
DCLK
high time for the first device in the configuration chain 50 125 250 ns
tMCL
DCLK
low time for the first device in the configuration chain 50 125 250 ns
tSCH
DCLK
high time for subsequent devices 50 ns
tSCL
DCLK
low time for subsequent devices 50 ns
tCASC
DCLK
rising edge to n
CASC
25 ns
tCCA n
CS
to n
CASC
cascade delay 15 ns
tOEW
OE
low pulse width (reset) to guarantee counter reset 100 ns
tOEC
OE
low (reset) to
DCLK
disable delay 30 ns
tNRCAS
OE
low (reset) to n
CASC
delay 30 ns
Note to Tabl e 9 :
(1) During initial power-up, a POR delay occurs to permit voltage levels to stabilize. Subsequent reconfigurations do not incur this delay.
Table 10. Timing Parameters when Using EPC1, EPC2, and EPC1441 Devices at 5.0 V (Part 1 of 2)
Symbol Parameter Min Typ Max Units
tPOR POR delay (1) ——200ms
tOEZX
OE
high to
DATA
output enabled 50 ns
tCE
OE
high to first rising edge on
DCLK
——200ns
tDSU
Data
setup time before rising edge on
DCLK
30 ns
tDH
Data
hold time after rising edge on
DCLK
0—ns
tCO
DCLK
to
DATA
out 20 ns
tCDOE
DCLK
to
DATA
enable/disable 20 ns
fCLK
DCLK
frequency 6.7 10 16.7 MHz
tMCH
DCLK
high time for the first device in the configuration chain 30 50 75 ns
tMCL
DCLK
low time for the first device in the configuration chain 30 50 75 ns
tSCH
DCLK
high time for subsequent devices 30 ns
tSCL
DCLK
low time for subsequent devices 30 ns
tCASC
DCLK
rising edge to n
CASC
20 ns
tCCA
nCS
to n
CASC
cascade delay 10 ns
Page 18 Timing Information
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
Tabl e 11 lists the timing parameters when using EPC1, EPC1064, EPC1064V, EPC1213,
and EPC1441 devices when configuring the FLEX 8000 device.
tOEW
OE
low pulse width (reset) to guarantee counter reset 100 ns
tOEC
OE
low (reset) to
DCLK
disable delay 20 ns
tNRCAS
OE
low (reset) to n
CASC
delay 25 ns
Note to Tabl e 1 0 :
(1) During initial power-up, a POR delay occurs to permit voltage levels to stabilize. Subsequent reconfigurations do not incur this delay.
Table 10. Timing Parameters when Using EPC1, EPC2, and EPC1441 Devices at 5.0 V (Part 2 of 2)
Symbol Parameter Min Typ Max Units
Table 11. FLEX 8000 Device Configuration Parameters Using EPC1, EPC1064, EPC1064V, EPC1213, and EPC1441
Devices
Symbol Parameter
EPC1064V EPC1064 and
EPC1213
EPC1 and
EPC1441 Unit
Min Max Min Max Min Max
t
OEZX
OE
high to
DATA
output enabled 75 50 50 ns
t
CSZX n
CS
low to
DATA
output enabled 75 50 50 ns
t
CSXZ n
CS
high to
DATA
output disabled 75 50 50 ns
t
CSS n
CS
low setup time to first
DCLK
rising edge 150 100 50 ns
t
CSH n
CS
low hold time after
DCLK
rising edge 0—0—0—ns
t
DSU
Data
setup time before rising edge on
DCLK
75 50 50 ns
t
DH
Data
hold time after rising edge on
DCLK
0—0—0—ns
t
CO
DCLK
to
DATA
out delay 100 75 75 ns
t
CK Clock period 240 160 100 ns
f
CK Clock frequency 4 6 8 MHz
t
CL
DCLK
low time 120 80 50 ns
t
CH
DCLK
high time 120 80 50 ns
t
XZ
OE
low or n
CS
high to
DATA
output disabled 75 50 50 ns
t
OEW
OE
pulse width to guarantee counter reset 150 100 100 ns
t
CASC Last
DCLK
+ 1 to n
CASC
low delay 90 60 50 ns
t
CKXZ Last
DCLK
+ 1 to
DATA
tri-state delay 75 50 50 ns
t
CEOUT n
CS
high to n
CASC
high delay 150 100 100 ns
Operating Conditions Page 19
Configuration Devices for SRAM-Based LUT DevicesJanuary 2012 Altera Corporation
Operating Conditions
Tabl e 12 through Table 19 list information about absolute maximum ratings,
recommended operating conditions, DC operating conditions, and capacitance for
configuration devices.
Table 12. Absolute Maximum Ratings (1)
Symbol Parameter Conditions Min Max Unit
V
CC Supply voltage With respect to GND (2) –2.0 7.0 V
V
IDC input voltage With respect to GND (2) –2.0 7.0 V
I
MAX DC VCC
or GND current 50 mA
I
OUT DC output current, per pin –25 25 mA
P
DPower dissipation 250 mW
T
STG Storage temperature No bias 65 150 ° C
T
AMB Ambient temperature Under bias –65 135 ° C
T
JJunction temperature Under bias 135 ° C
Table 13. Recommended Operating Conditions
Symbol Parameter Conditions Min Max Unit
V
CC
Supply voltage for 5.0-V operation (3), (4) 4.75
(4.50)
5.25
(5.50) V
Supply voltage for 3.3-V operation (3), (4) 3.0 (3.0) 3.6 (3.6) V
V
IInput voltage With respect to GND 0.3 VCC + 0.3
(5) V
V
OOutput voltage 0 VCC V
T
AOperating temperature For commercial use 0 70 ° C
For industrial use 40 85 ° C
t
RInput rise time 20 ns
t
FInput fall time 20 ns
Table 14. DC Operating Conditions
Symbol Parameter Conditions Min Max Unit
V
IH High-level input voltage 2.0 VCC + 0.3
(5) V
V
IL Low-level input voltage –0.3 0.8 V
V
OH
5.0-V mode high-level TTL output
voltage IOH = –4 mA DC (6) 2.4 V
3.3-V mode high-level CMOS
output voltage IOH = –0.1 mA DC (6) VCC0.2 V
V
OL Low-level output voltage IOL = 4 mA DC (6) —0.4 V
I
IInput leakage current VI = VCC or GND –10 10 A
I
OZ Tri-state output off-state current VO = VCC or GND 10 10 A
Page 20 Operating Conditions
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
Table 15. EPC1064, EPC1064V, and EPC1213 Devices ICC Supply Current Values
Symbol Parameter Conditions Min Typ Max Unit
I
CC0 VCC supply current (standby) 100 200 A
I
CC1 VCC supply current (during configuration) 10 50 mA
Table 16. EPC2 Device Values
Symbol Parameter Conditions Min Typ Max Unit
I
CC0 VCC supply current (standby) VCC = 5.0 V or 3.3 V 50 100 µA
I
CC1
VCC supply current (during
configuration) VCC = 5.0 V or 3.3 V 18 50 mA
R
CONF Configuration pins Internal pull up (
OE
, n
CS
,
n
INIT
_
CONF
)—1k
Table 17. EPC1 Device ICC Supply Current Values
Symbol Parameter Conditions Min Typ Max Unit
I
CC0 VCC supply current (standby) 50 100 µA
I
CC1 VCC supply current (during configuration) VCC = 5.0 V 30 50 mA
VCC = 3.3 V 10 16.5 mA
Table 18. EPC1441 Device ICC Supply Current Values
Symbol Parameter Conditions Min Typ Max Unit
I
CC0 VCC supply current (standby) 30 60 µA
I
CC1 VCC supply current (during configuration) VCC = 5.0 V 15 30 mA
I
CC1 VCC supply current (during configuration) VCC = 3.3 V 5 10 mA
Table 19. Capacitance (7)
Symbol Parameter Conditions Min Max Unit
C
IN Input pin capacitance VIN = 0 V, f = 1.0 MHz 10 pF
C
OUT Output pin capacitance VOUT = 0 V, f = 1.0 MHz 10 pF
Notes to Table 12 through Ta ble 19:
(1) For more information, refer to the Operating Requirements for Altera Devices Datasheet.
(2) The minimum DC input is -0.3 V. During transitions, the inputs may undershoot to -2.0 V or overshoot to 7.0 V for input currents less than
100 mA and periods shorter than 20 ns under no-load conditions.
(3) Numbers in parentheses are for industrial temperature range devices.
(4) Maximum VCC rise time is 100 ms.
(5) Certain EPC2 device pins are driven to 5.75 V when operated with a 3.3-V VCC. For more information, refer to Table 4 on page 11.
(6) The IOH parameter refers to high-level TTL or CMOS output current and the IOL parameter refers to low-level TTL or CMOS output current.
(7) Capacitance is sample tested only.
Pin Information Page 21
Configuration Devices for SRAM-Based LUT DevicesJanuary 2012 Altera Corporation
Pin Information
Tabl e 20 lists the pin functions of the EPC1, EPC2, and EPC1441 devices during device
configuration.
fFor more information about pin information of EPC devices, refer to the Enhanced
Configuration (EPC) Devices Datasheet.
fFor more information about pin information of EPCS devices, refer to the Serial
Configuration (EPCS) Devices Datasheet.
Table 20. EPC1, EPC2, and EPC1441 Device Pin Functions During Configuration (Part 1 of 3)
Pin Name
Pin Number
Pin Type Description
8-Pin
PDIP (1 )
20-Pin
PLCC
32-Pin
TQFP (2)
DATA
1231Output
Serial data output. The
DATA
pin connects to the
DATA0
pin
of the FPGA.
DATA
is latched into the FPGA on the rising
edge of
DCLK
.
The
DATA
pin is tri-stated before configuration and when
the n
CS
pin is high. After configuration, the EPC2 device
drives
DATA
high, while the EPC1 and EPC1441 device
tri-state
DATA
.
DCLK
2 4 2 Bidirectional
Clock output when configuring with a single configuration
device or when the configuration device is the first
(master) device in a chain. Clock input for the next (slave)
configuration devices in a chain. The
DCLK
pin connects to
the
DCLK
pin of the FPGA.
Rising edges on
DCLK
increment the internal address
counter and present the next bit of data on the
DATA
pin.
The counter is incremented only if the
OE
input is held
high, the n
CS
input is held low, and all configuration data
has not been transferred to the target device.
After configuration or when
OE
is low, the EPC1, EPC2 and
EPC1441 device drive
DCLK
low.
OE
387
Open-drain
bidirectional
Output enable (active high) and reset (active low). The
OE
pin connects to the n
STATUS
pin of the FPGA.
A low logic level resets the address counter. A high logic
level enables
DATA
and the address counter to count. If this
pin is low (reset) during configuration, the internal
oscillator becomes inactive and
DCLK
drives low. For more
information, refer to Error Detection Circuitry” on page 9.
The
OE
pin has an internal programmable 1-k resistor in
EPC2 devices. If internal pull-up resistors are used, do not
use external pull-up resistors on these pins. You can
disable the internal pull-up resistors through the Disable
nCS and OE pull-ups on configuration device option.
Page 22 Pin Information
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
n
CS
4910Input
Chip select input (active low). The n
CS
pin connects to the
CONF
_
DONE
pin of the FPGA.
A low input allows
DCLK
to increment the address counter
and enables
DATA
to drive out. If the EPC1 or EPC2 device
is reset (
OE
pulled low) while n
CS
is low, the device
initializes as the master device in a configuration chain. If
the EPC1 or EPC2 device is reset (
OE
pulled low) while n
CS
is high, the device initializes as a slave device in the chain.
The n
CS
pin has an internal programmable 1-k resistor
in EPC2 devices. If internal pull-up resistors are used, do
not use external pull-up resistors on these pins. You can
disable the internal pull-up resistors through the Disable
nCS and OE pull-ups on configuration device option.
n
CASC
61215Output
Cascade select output (active low).
This output goes low when the address counter has
reached its maximum value. When the address counter has
reached its maximum value, the configuration device has
sent all its configuration data to the FPGA. In a chain of
EPC1 or EPC2 devices, the n
CASC
pin of one device is
connected to the n
CS
pin of the next device, which permits
DCLK
to clock data from the next EPC1 or EPC2 device in
the chain. For single EPC1 or EPC2 device and the last
device in the chain, n
CASC
is left floating.
This pin is only available in EPC1 and EPC2 devices, which
support data cascading.
n
INIT
_
CONF
N/A 13 16 Open-Drain
Output
Allows the
INIT
_
CONF
JTAG instruction to initiate
configuration. The n
INIT
_
CONF
pin connects to the
n
CONFIG
pin of the FPGA.
If multiple EPC2 devices are used to configure an FPGA,
the n
INIT
_
CONF
of the first EPC2 device pin is tied to the
FPGA’s n
CONFIG
pin, while subsequent devices'
n
INIT
_
CONF
pins are left floating.
The
INIT
_
CONF
pin has an internal 1-k pull-up resistor
that is always active in EPC2 devices.
This pin is only available in EPC2 devices.
TDI
N/A 11 13 Input
JTAG data input pin. Connect this pin to VCC
if the JTAG
circuitry is not used.
This pin is only available in EPC2 devices.
TDO
N/A 1 28 Output
JTAG data output pin. Do not connect this pin if the JTAG
circuitry is not used.
This pin is only available in EPC2 devices.
TMS
N/A 19 25 Input
JTAG mode select pin. Connect this pin to VCC if the JTAG
circuitry is not used.
This pin is only available in EPC2 devices.
Table 20. EPC1, EPC2, and EPC1441 Device Pin Functions During Configuration (Part 2 of 3)
Pin Name
Pin Number
Pin Type Description
8-Pin
PDIP (1 )
20-Pin
PLCC
32-Pin
TQFP (2)
Pin Information Page 23
Configuration Devices for SRAM-Based LUT DevicesJanuary 2012 Altera Corporation
TCK
N/A 3 32 Input
JTAG clock pin. Connect this pin to GND if the JTAG
circuitry is not used.
This pin is only available in EPC2 devices.
VCCSEL
N/A 5 3 Input
Mode select for VCC supply.
VCCSEL
must be connected to
GND if the device uses a 5.0-V power supply (VCC = 5.0 V).
VCCSEL
must be connected to VCC if the device uses a
3.3-V power supply (VCC
= 3.3 V).
This pin is only available in EPC2 devices.
VPPSEL
N/A 14 17 Input
Mode select for
V
PP
. supply.
VPPSEL
must be connected to
GND if VPP uses a 5.0-V power supply (VPP = 5.0 V).
VPPSEL
must be connected to VCC if VPP uses a 3.3-V
power supply (VPP = 3.3 V).
This pin is only available in EPC2 devices.
VPP
N/A 18 23 Power
Programming power pin. For the EPC2 device, this pin is
normally tied to VCC. If the VCC of the EPC2 device is 3.3 V,
tie VPP to 5.0 V to improve ISP time. For EPC1 and
EPC1441 devices, VPP must be tied to VCC.
This pin is only available in EPC2 devices.
VCC
7, 8 20 27 Power Power pin.
GND 5 10 12 Ground Ground pin. Place a 0.2-µF decoupling capacitor between
the VCC and GND pins.
Notes to Table 20 :
(1) This package is available for EPC1 and EPC1441 devices only.
(2) This package is available for EPC2 and EPC1441 devices only.
Table 20. EPC1, EPC2, and EPC1441 Device Pin Functions During Configuration (Part 3 of 3)
Pin Name
Pin Number
Pin Type Description
8-Pin
PDIP (1 )
20-Pin
PLCC
32-Pin
TQFP (2)
Page 24 Package
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
Package
Figure 6 and Figure 7 show the configuration device package pin-outs.
fFor more information about package outlines and drawings, refer to the Package and
Thermal Resistance page.
Figure 6. EPC1, EPC1064, EPC1064V, EPC1213, and EPC1441 Package Pin-Out Diagrams (1)
Notes to Figure 6:
(1) EPC1 and EPC1441 devices are one-time programmable devices. ISP is not available in these devices.
(2) The n
CASC
pin is available on EPC1 devices, which allows them to be cascaded. For EPC1441 devices, n
CASC
is a reserved pin and should
be left unconnected.
Figure 7. EPC2 Package Pin-Out Diagrams
8-Pin PDIP 32-Pin TQFP
EPC1441
EPC1064
EPC1064V
20-Pin PLCC
EPC1
EPC1441
EPC1213
EPC1064
EPC1064V
EPC1
EPC1441
EPC1213
EPC1064
EPC1064V
DATA
DCLK
OE
nCS
VCC
VCC
nCASC (2)
GND
1
2
3
4
8
7
6
5
123
4
5
6
7
8
20 19
10 13
18
17
16
15
14
OE
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
DCLK
N.C.
N.C.
N.C.
DATA
VCC
VCC
N.C.
N.C.
(2) nCASC
nCS
GND
303132
1
2
3
4
5
29 28
DCLK
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
nCS
GND
24
23
22
21
20
VCC
19
18
17
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
N.C.
DATA
VCC
25
916
8
OE
6
7
10 11 12 13 14 15
27 26
91112
32-Pin TQFP
20-Pin PLCC
123
4
5
6
7
8
20 19
111091213
18
17
16
15
14
OE
N.C.
VCCSEL
DCLK
N.C.
TMS
TCK
DATA
TDO
VCC
VPP
N.C.
N.C.
N.C.
VPPSEL
TDI
nCASC
nCS
GND
303132
1
2
3
4
5
29 28
N.C.
N.C.
DCLK
N.C.
VCCSEL
TDI
N.C.
nCS
N.C.
GND
nINIT_CONF
N.C.
N.C.
24
23
22
21
20
N.C.
VPP
N.C.
N.C.
19
18
17
TDO
TCK
DATA
N.C.
N.C.
TMS
VCC
N.C.
25
916
8
N.C.
OE
N.C.
VPPSEL
N.C.
N.C.
6
7
10 11 12 13 14 15
27 26
nCASC
nINIT_CONF
Ordering Codes Page 25
Configuration Devices for SRAM-Based LUT DevicesJanuary 2012 Altera Corporation
Ordering Codes
Tabl e 21 lists the ordering codes for the EPC1, EPC2, and EPC1441 configuration
devices.
Document Revision History
Tabl e 22 lists the revision history for this document.
Table 21. Configuration Device Ordering Codes
Device Package Temperature Ordering Code
EPC1 20-pin PLCC Commercial EPC1LC20
EPC1 20-pin PLCC Industrial EPC1LI20
EPC1 8-pin PDIP Commercial EPC1PC8
EPC1 8-pin PDIP Industrial EPC1PI8
EPC2 32-pin TQFP Commercial EPC2TC32
EPC2 32-pin TQFP Industrial EPC2TI32
EPC2 20-pin PLCC Commercial EPC2LC20
EPC2 20-pin PLCC Industrial EPC2LI20
EPC1441 32-pin TQFP Commercial EPC1441TC32
EPC1441 32-pin TQFP Industrial EPC1441TI32
EPC1441 20-pin PLCC Commercial EPC1441LC20
EPC1441 20-pin PLCC Industrial EPC1441LI20
EPC1441 8-pin PDIP Commercial EPC1441PC8
EPC1441 8-pin PDIP Industrial EPC1441PI8
Table 22. Document Revision History
Date Version Changes
January 2012 3.0 Minor text edits.
December 2009 2.4
Updated “Featuressection.
Removed “Referenced Documents” section.
October 2008 2.3
Updated “Featuresand “IEEE Std. 1149.1 (JTAG) Boundary-Scan Testing”
sections.
Updated Table 5–2 and Table 5–16.
AddedReferenced Documents” section.
Updated new document format.
April 2007 2.2 Added document revision history.
July 2004 2.0 Added Stratix II and Cyclone II device information throughout chapter.
September 2003 1.0 Initial Release.
Page 26 Document Revision History
Configuration Devices for SRAM-Based LUT Devices January 2012 Altera Corporation
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EPC1PI8N EPC1064PC8 EPC1441PC8 EPC2LI20 EPC1LI20N EPC2TI32 EPC1441LC20N EPC1441LI20N
EPC1064LC20 EPC1PI8 EPC1213LI20 EPC2TC32N EPC1LI20 EPC1441TC32N EPC2TI32N EPC1441TI32N
EPC1PC8 EPC1441TC32 EPC2LC20N EPC1064PI8 EPC1441LI20 EPC1LC20N EPC1441TI32 EPC1441PI8
EPC1441LC20 EPC2TC32 EPC1213PI8 EPC1213LC20 EPC2LI20N EPC1213PC8 EPC1LC20 EPC2LC20