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Virtex™ 2.5 V
Field Programmable Gate Arrays
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0
Product Specification
Features
•
•
•
•
•
Fast, high-density Field Programmable Gate Arrays
- Densities from 50k to 1M system gates
- System performance up to 200 MHz
- 66-MHz PCI Compliant
- Hot-swappable for Compact PCI
Multi-standard SelectIO™ interfaces
- 16 high-performance interface standards
- Connects directly to ZBTRAM devices
Built-in clock-management circuitry
- Four dedicated delay-locked loops (DLLs) for
advanced clock control
- Four primary low-skew global clock distribution
nets, plus 24 secondary local clock nets
Hierarchical memory system
- LUTs configurable as 16-bit RAM, 32-bit RAM,
16-bit dual-ported RAM, or 16-bit Shift Register
- Configurable synchronous dual-ported 4k-bit
RAMs
- Fast interfaces to external high-performance RAMs
Flexible architecture that balances speed and density
- Dedicated carry logic for high-speed arithmetic
- Dedicated multiplier support
- Cascade chain for wide-input functions
- Abundant registers/latches with clock enable, and
dual synchronous/asynchronous set and reset
- Internal 3-state bussing
- IEEE 1149.1 boundary-scan logic
- Die-temperature sensor diode
•
•
•
•
Supported by FPGA Foundation™ and Alliance
Development Systems
- Complete support for Unified Libraries, Relationally
Placed Macros, and Design Manager
- Wide selection of PC and workstation platforms
SRAM-based in-system configuration
- Unlimited re-programmability
- Four programming modes
0.22 μm 5-layer metal process
100% factory tested
Description
The Virtex FPGA family delivers high-performance,
high-capacity programmable logic solutions. Dramatic
increases in silicon efficiency result from optimizing the new
architecture for place-and-route efficiency and exploiting an
aggressive 5-layer-metal 0.22 μm CMOS process. These
advances make Virtex FPGAs powerful and flexible alternatives to mask-programmed gate arrays. The Virtex family
comprises the nine members shown in Table 1.
Building on experience gained from previous generations of
FPGAs, the Virtex family represents a revolutionary step
forward in programmable logic design. Combining a wide
variety of programmable system features, a rich hierarchy of
fast, flexible interconnect resources, and advanced process
technology, the Virtex family delivers a high-speed and
high-capacity programmable logic solution that enhances
design flexibility while reducing time-to-market.
Table 1: Virtex Field Programmable Gate Array Family Members
Device
System Gates
CLB Array
Logic Cells
Maximum
Available I/O
Block RAM
Bits
Maximum
SelectRAM+™ Bits
XCV50
57,906
16x24
1,728
180
32,768
24,576
XCV100
108,904
20x30
2,700
180
40,960
38,400
XCV150
164,674
24x36
3,888
260
49,152
55,296
XCV200
236,666
28x42
5,292
284
57,344
75,264
XCV300
322,970
32x48
6,912
316
65,536
98,304
XCV400
468,252
40x60
10,800
404
81,920
153,600
XCV600
661,111
48x72
15,552
512
98,304
221,184
XCV800
888,439
56x84
21,168
512
114,688
301,056
XCV1000
1,124,022
64x96
27,648
512
131,072
393,216
© 2001-2013 Xilinx, Inc. All rights reserved. All Xilinx trademarks, registered trademarks, patents, and disclaimers are as listed at http://www.xilinx.com/legal.htm.
All other trademarks and registered trademarks are the property of their respective owners. All specifications are subject to change without notice.
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Virtex™ 2.5 V Field Programmable Gate Arrays
Virtex Architecture
Virtex devices feature a flexible, regular architecture that
comprises an array of configurable logic blocks (CLBs) surrounded by programmable input/output blocks (IOBs), all
interconnected by a rich hierarchy of fast, versatile routing
resources. The abundance of routing resources permits the
Virtex family to accommodate even the largest and most
complex designs.
Virtex FPGAs are SRAM-based, and are customized by
loading configuration data into internal memory cells. In
some modes, the FPGA reads its own configuration data
from an external PROM (master serial mode). Otherwise,
the configuration data is written into the FPGA (SelectMAP™, slave serial, and JTAG modes).
The standard Xilinx Foundation™ and Alliance Series™
Development systems deliver complete design support for
Virtex, covering every aspect from behavioral and schematic entry, through simulation, automatic design translation and implementation, to the creation, downloading, and
readback of a configuration bit stream.
Xilinx thoroughly benchmarked the Virtex family. While performance is design-dependent, many designs operated
internally at speeds in excess of 100 MHz and can achieve
200 MHz. Table 2 shows performance data for representative circuits, using worst-case timing parameters.
Table 2: Performance for Common Circuit Functions
Function
Module 1 of 4
2
Virtex -6
16
5.0 ns
64
7.2 ns
8x8
5.1 ns
16 x 16
6.0 ns
16
4.4 ns
64
6.4 ns
Register-to-Register
Adder
Pipelined Multiplier
Address Decoder
16:1 Multiplexer
Parity Tree
Higher Performance
Virtex devices provide better performance than previous
generations of FPGA. Designs can achieve synchronous
system clock rates up to 200 MHz including I/O. Virtex
inputs and outputs comply fully with PCI specifications, and
interfaces can be implemented that operate at 33 MHz or
66 MHz. Additionally, Virtex supports the hot-swapping
requirements of Compact PCI.
Bits
5.4 ns
9
4.1 ns
18
5.0 ns
36
6.9 ns
Chip-to-Chip
HSTL Class IV
200 MHz
LVTTL,16mA, fast slew
180 MHz
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Virtex™ 2.5 V Field Programmable Gate Arrays
Virtex Device/Package Combinations and Maximum I/O
Table 3: Virtex Family Maximum User I/O by Device/Package (Excluding Dedicated Clock Pins)
Package
XCV50
XCV100
CS144
94
94
TQ144
98
98
PQ240
166
166
XCV150
XCV200
XCV300
166
166
166
XCV400
XCV600
XCV800
166
166
166
316
316
316
404
404
404
404
444
444
512
512
HQ240
BG256
180
180
BG352
180
180
260
260
BG432
260
316
BG560
FG256
176
176
FG456
176
176
260
284
XCV1000
404
312
FG676
FG680
512
Virtex Ordering Information
Example:
Device Type
Speed Grade
-4
-5
-6
XCV300 -6 PQ 240 C
Temperature Range
C = Commercial (TJ = 0°C to +85°C)
I = Industrial (TJ = –40°C to +100°C)
Number of Pins
Package Type
BG = Ball Grid Array
FG = Fine-pitch Ball Grid Array
PQ = Plastic Quad Flat Pack
HQ = High Heat Dissipation QFP
TQ = Thin Quad Flat Pack
CS = Chip-scale Package
Figure 1: Virtex Ordering Information
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Revision History
Date
Version
Revision
11/98
1.0
01/99-02/99
1.2-1.3
05/99
1.4
Addition of package drawings and specifications.
05/99
1.5
Replaced FG 676 & FG680 package drawings.
07/99
1.6
Changed Boundary Scan Information and changed Figure 11, Boundary Scan Bit
Sequence. Updated IOB Input & Output delays. Added Capacitance info for different I/O
Standards. Added 5 V tolerant information. Added DLL Parameters and waveforms and
new Pin-to-pin Input and Output Parameter tables for Global Clock Input to Output and
Setup and Hold. Changed Configuration Information including Figures 12, 14, 17 & 19.
Added device-dependent listings for quiescent currents ICCINTQ and ICCOQ. Updated
IOB Input and Output Delays based on default standard of LVTTL, 12 mA, Fast Slew Rate.
Added IOB Input Switching Characteristics Standard Adjustments.
09/99
1.7
Speed grade update to preliminary status, Power-on specification and Clock-to-Out
Minimums additions, “0” hold time listing explanation, quiescent current listing update, and
Figure 6 ADDRA input label correction. Added TIJITCC parameter, changed TOJIT to
TOPHASE.
01/00
1.8
Update to speed.txt file 1.96. Corrections for CRs 111036,111137, 112697, 115479,
117153, 117154, and 117612. Modified notes for Recommended Operating Conditions
(voltage and temperature). Changed Bank information for VCCO in CS144 package on p.43.
01/00
1.9
Updated DLL Jitter Parameter table and waveforms, added Delay Measurement
Methodology table for different I/O standards, changed buffered Hex line info and
Input/Output Timing measurement notes.
03/00
2.0
New TBCKO values; corrected FG680 package connection drawing; new note about status
of CCLK pin after configuration.
05/00
2.1
Modified “Pins not listed...” statement. Speed grade update to Final status.
05/00
2.2
Modified Table 18.
09/00
2.3
•
•
•
Added XCV400 values to table under Minimum Clock-to-Out for Virtex Devices.
Corrected Units column in table under IOB Input Switching Characteristics.
Added values to table under CLB SelectRAM Switching Characteristics.
10/00
2.4
•
•
Corrected Pinout information for devices in the BG256, BG432, and BG560 packages in
Table 18.
Corrected BG256 Pin Function Diagram.
04/01
2.5
•
•
Revised minimums for Global Clock Set-Up and Hold for LVTTL Standard, with DLL.
Converted file to modularized format. See Virtex Data Sheet section.
03/13
4.0
Initial Xilinx release.
Both versions updated package drawings and specs.
The products listed in this data sheet are obsolete. See XCN10016 for further information.
Virtex Data Sheet
The Virtex Data Sheet contains the following modules:
•
DS003-1, Virtex 2.5V FPGAs:
Introduction and Ordering Information (Module 1)
•
DS003-3, Virtex 2.5V FPGAs:
DC and Switching Characteristics (Module 3)
•
DS003-2, Virtex 2.5V FPGAs:
Functional Description (Module 2)
•
DS003-4, Virtex 2.5V FPGAs:
Pinout Tables (Module 4)
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Virtex™ 2.5 V
Field Programmable Gate Arrays
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Architectural Description
The output buffer and all of the IOB control signals have
independent polarity controls.
VersaRing
The Virtex architecture also includes the following circuits
that connect to the GRM.
•
•
•
Dedicated block memories of 4096 bits each
Clock DLLs for clock-distribution delay compensation
and clock domain control
3-State buffers (BUFTs) associated with each CLB that
drive dedicated segmentable horizontal routing
resources
Values stored in static memory cells control the configurable
logic elements and interconnect resources. These values
load into the memory cells on power-up, and can reload if
necessary to change the function of the device.
Input/Output Block
The Virtex IOB, Figure 2, features SelectIO™ inputs and
outputs that support a wide variety of I/O signalling standards, see Table 1.
The three IOB storage elements function either as edge-triggered D-type flip-flops or as level sensitive latches. Each
IOB has a clock signal (CLK) shared by the three flip-flops
and independent clock enable signals for each flip-flop.
In addition to the CLK and CE control signals, the three
flip-flops share a Set/Reset (SR). For each flip-flop, this signal can be independently configured as a synchronous Set,
a synchronous Reset, an asynchronous Preset, or an asynchronous Clear.
IOBs
The VersaRing™ I/O interface provides additional routing
resources around the periphery of the device. This routing
improves I/O routability and facilitates pin locking.
CLBs
BRAMs
CLBs interconnect through a general routing matrix (GRM).
The GRM comprises an array of routing switches located at
the intersections of horizontal and vertical routing channels.
Each CLB nests into a VersaBlock™ that also provides local
routing resources to connect the CLB to the GRM.
DLL
IOBs
VersaRing
•
CLBs provide the functional elements for constructing
logic
IOBs provide the interface between the package pins
and the CLBs
DLL
BRAMs
The Virtex user-programmable gate array, shown in
Figure 1, comprises two major configurable elements: configurable logic blocks (CLBs) and input/output blocks
(IOBs).
VersaRing
Virtex Array
•
Product Specification
IOBs
DS003-2 (v4.0) March 1, 2013
VersaRing
DLL
IOBs
DLL
vao_b.eps
Figure 1: Virtex Architecture Overview
All pads are protected against damage from electrostatic
discharge (ESD) and from over-voltage transients. Two
forms of over-voltage protection are provided, one that permits 5 V compliance, and one that does not. For 5 V compliance, a Zener-like structure connected to ground turns on
when the output rises to approximately 6.5 V. When PCI
3.3 V compliance is required, a conventional clamp diode is
connected to the output supply voltage, VCCO.
Optional pull-up and pull-down resistors and an optional
weak-keeper circuit are attached to each pad. Prior to configuration, all pins not involved in configuration are forced
into their high-impedance state. The pull-down resistors and
the weak-keeper circuits are inactive, but inputs can optionally be pulled up.
The activation of pull-up resistors prior to configuration is
controlled on a global basis by the configuration mode pins.
If the pull-up resistors are not activated, all the pins will float.
Consequently, external pull-up or pull-down resistors must
be provided on pins required to be at a well-defined logic
level prior to configuration.
All Virtex IOBs support IEEE 1149.1-compatible boundary
scan testing.
© 1999-2013 Xilinx, Inc. All rights reserved. All Xilinx trademarks, registered trademarks, patents, and disclaimers are as listed at http://www.xilinx.com/legal.htm.
All other trademarks and registered trademarks are the property of their respective owners. All specifications are subject to change without notice.
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Virtex™ 2.5 V Field Programmable Gate Arrays
T
TCE
D Q
CE
Weak
Keeper
SR
O
OCE
PAD
D Q
CE
OBUFT
SR
I
IQ
Q
Programmable
Delay
D
CE
IBUF
Vref
SR
SR
CLK
ICE
ds022_02_091300
Figure 2: Virtex Input/Output Block (IOB)
Table 1: Supported Select I/O Standards
Input Reference
Voltage (VREF)
Output Source
Voltage (VCCO)
Board Termination
Voltage (VTT)
5 V Tolerant
LVTTL 2 – 24 mA
N/A
3.3
N/A
Yes
LVCMOS2
N/A
2.5
N/A
Yes
PCI, 5 V
N/A
3.3
N/A
Yes
PCI, 3.3 V
N/A
3.3
N/A
No
GTL
0.8
N/A
1.2
No
GTL+
1.0
N/A
1.5
No
HSTL Class I
0.75
1.5
0.75
No
HSTL Class III
0.9
1.5
1.5
No
HSTL Class IV
0.9
1.5
1.5
No
SSTL3 Class I &II
1.5
3.3
1.5
No
SSTL2 Class I & II
1.25
2.5
1.25
No
CTT
1.5
3.3
1.5
No
AGP
1.32
3.3
N/A
No
I/O Standard
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Virtex™ 2.5 V Field Programmable Gate Arrays
An optional delay element at the D-input of this flip-flop eliminates pad-to-pad hold time. The delay is matched to the
internal clock-distribution delay of the FPGA, and when
used, assures that the pad-to-pad hold time is zero.
Bank 0
Bank 7
Each input buffer can be configured to conform to any of the
low-voltage signalling standards supported. In some of
these standards the input buffer utilizes a user-supplied
threshold voltage, VREF. The need to supply VREF imposes
constraints on which standards can used in close proximity
to each other. See I/O Banking, page 3.
Bank 6
Virtex
Device
There are optional pull-up and pull-down resistors at each
user I/O input for use after configuration. Their value is in
the range 50 kΩ – 100 kΩ.
GCLK1 GCLK0
Bank 5
Bank 4
X8778_b
Output Path
The output path includes a 3-state output buffer that drives
the output signal onto the pad. The output signal can be
routed to the buffer directly from the internal logic or through
an optional IOB output flip-flop.
The 3-state control of the output can also be routed directly
from the internal logic or through a flip-flip that provides synchronous enable and disable.
Each output driver can be individually programmed for a
wide range of low-voltage signalling standards. Each output
buffer can source up to 24 mA and sink up to 48mA. Drive
strength and slew rate controls minimize bus transients.
In most signalling standards, the output High voltage
depends on an externally supplied VCCO voltage. The need
to supply VCCO imposes constraints on which standards
can be used in close proximity to each other. See I/O Banking, page 3.
An optional weak-keeper circuit is connected to each output. When selected, the circuit monitors the voltage on the
pad and weakly drives the pin High or Low to match the
input signal. If the pin is connected to a multiple-source signal, the weak keeper holds the signal in its last state if all
drivers are disabled. Maintaining a valid logic level in this
way eliminates bus chatter.
Because the weak-keeper circuit uses the IOB input buffer
to monitor the input level, an appropriate VREF voltage must
be provided if the signalling standard requires one. The provision of this voltage must comply with the I/O banking
rules.
I/O Banking
Some of the I/O standards described above require VCCO
and/or VREF voltages. These voltages externally and connected to device pins that serve groups of IOBs, called
banks. Consequently, restrictions exist about which I/O
standards can be combined within a given bank.
DS003-2 (v4.0) March 1, 2013
Product Specification
Bank 1
GCLK3 GCLK2
Bank 2
A buffer In the Virtex IOB input path routes the input signal
either directly to internal logic or through an optional input
flip-flop.
Eight I/O banks result from separating each edge of the
FPGA into two banks, as shown in Figure 3. Each bank has
multiple VCCO pins, all of which must be connected to the
same voltage. This voltage is determined by the output
standards in use.
Bank 3
Input Path
Figure 3: Virtex I/O Banks
Within a bank, output standards can be mixed only if they
use the same VCCO. Compatible standards are shown in
Table 2. GTL and GTL+ appear under all voltages because
their open-drain outputs do not depend on VCCO.
Table 2: Compatible Output Standards
VCCO
Compatible Standards
3.3 V
PCI, LVTTL, SSTL3 I, SSTL3 II, CTT, AGP, GTL,
GTL+
2.5 V
SSTL2 I, SSTL2 II, LVCMOS2, GTL, GTL+
1.5 V
HSTL I, HSTL III, HSTL IV, GTL, GTL+
Some input standards require a user-supplied threshold
voltage, VREF. In this case, certain user-I/O pins are automatically configured as inputs for the VREF voltage. Approximately one in six of the I/O pins in the bank assume this
role.
The VREF pins within a bank are interconnected internally
and consequently only one VREF voltage can be used within
each bank. All VREF pins in the bank, however, must be connected to the external voltage source for correct operation.
Within a bank, inputs that require VREF can be mixed with
those that do not. However, only one VREF voltage can be
used within a bank. Input buffers that use VREF are not 5 V
tolerant. LVTTL, LVCMOS2, and PCI 33 MHz 5 V, are 5 V
tolerant.
The VCCO and VREF pins for each bank appear in the device
Pinout tables and diagrams. The diagrams also show the
bank affiliation of each I/O.
Within a given package, the number of VREF and VCCO pins
can vary depending on the size of device. In larger devices,
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more I/O pins convert to VREF pins. Since these are always
a superset of the VREF pins used for smaller devices, it is
possible to design a PCB that permits migration to a larger
device if necessary. All the VREF pins for the largest device
anticipated must be connected to the VREF voltage, and not
used for I/O.
In smaller devices, some VCCO pins used in larger devices
do not connect within the package. These unconnected pins
can be left unconnected externally, or can be connected to
the VCCO voltage to permit migration to a larger device if
necessary.
In TQ144 and PQ/HQ240 packages, all VCCO pins are
bonded together internally, and consequently the same
VCCO voltage must be connected to all of them. In the
CS144 package, bank pairs that share a side are interconnected internally, permitting four choices for VCCO. In both
cases, the VREF pins remain internally connected as eight
banks, and can be used as described previously.
Configurable Logic Block
The basic building block of the Virtex CLB is the logic cell
(LC). An LC includes a 4-input function generator, carry
logic, and a storage element. The output from the function
generator in each LC drives both the CLB output and the D
input of the flip-flop. Each Virtex CLB contains four LCs,
organized in two similar slices, as shown in Figure 4.
Figure 5 shows a more detailed view of a single slice.
In addition to the four basic LCs, the Virtex CLB contains
logic that combines function generators to provide functions
of five or six inputs. Consequently, when estimating the
number of system gates provided by a given device, each
CLB counts as 4.5 LCs.
Look-Up Tables
Virtex function generators are implemented as 4-input
look-up tables (LUTs). In addition to operating as a function
generator, each LUT can provide a 16 x 1-bit synchronous
RAM. Furthermore, the two LUTs within a slice can be combined to create a 16 x 2-bit or 32 x 1-bit synchronous RAM,
or a 16x1-bit dual-port synchronous RAM.
The Virtex LUT can also provide a 16-bit shift register that is
ideal for capturing high-speed or burst-mode data. This
mode can also be used to store data in applications such as
Digital Signal Processing.
Storage Elements
The storage elements in the Virtex slice can be configured
either as edge-triggered D-type flip-flops or as level-sensitive latches. The D inputs can be driven either by the function generators within the slice or directly from slice inputs,
bypassing the function generators.
In addition to Clock and Clock Enable signals, each Slice
has synchronous set and reset signals (SR and BY). SR
forces a storage element into the initialization state specified for it in the configuration. BY forces it into the opposite
state. Alternatively, these signals can be configured to operate asynchronously. All of the control signals are independently invertible, and are shared by the two flip-flops within
the slice.
COUT
COUT
YB
Y
G4
G3
G2
LUT
Carry &
Control
SP
D Q
EC
G3
YQ
G1
YB
Y
G4
LUT
G2
Carry &
Control
SP
D Q
EC
YQ
G1
RC
BY
RC
BY
XB
X
F4
F3
F2
LUT
Carry &
Control
F1
SP
D Q
EC
F3
XQ
X
LUT
F2
Carry &
Control
SP
D Q
EC
XQ
F1
RC
BX
XB
F4
RC
BX
Slice 1
Slice 0
slice_c.eps
CIN
CIN
Figure 4: 2-Slice Virtex CLB
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Virtex™ 2.5 V Field Programmable Gate Arrays
COUT
YB
CY
G4
G3
G2
G1
I3
I2
I1
I0
Y
O
LUT
0
INIT
D Q
EC
1
REV
DI
WE
YQ
BY
XB
F5IN
F6
CY
F5
F5
CK
WE
A4
BY DG
WSO
X
WSH
BX
DI
INIT
D Q
EC
BX
F4
F3
F2
F1
I3
I2
I1
I0
WE
LUT
XQ
DI
REV
O
0
1
SR
CLK
CE
CIN
viewslc4.eps
Figure 5: Detailed View of Virtex Slice
Additional Logic
Block SelectRAM
The F5 multiplexer in each slice combines the function generator outputs. This combination provides either a function
generator that can implement any 5-input function, a 4:1
multiplexer, or selected functions of up to nine inputs.
Similarly, the F6 multiplexer combines the outputs of all four
function generators in the CLB by selecting one of the
F5-multiplexer outputs. This permits the implementation of
any 6-input function, an 8:1 multiplexer, or selected functions of up to 19 inputs.
Each CLB has four direct feedthrough paths, one per LC.
These paths provide extra data input lines or additional local
routing that does not consume logic resources.
Virtex FPGAs incorporate several large block SelectRAM
memories. These complement the distributed LUT
SelectRAMs that provide shallow RAM structures implemented in CLBs.
Arithmetic Logic
Dedicated carry logic provides fast arithmetic carry capability for high-speed arithmetic functions. The Virtex CLB supports two separate carry chains, one per Slice. The height
of the carry chains is two bits per CLB.
The arithmetic logic includes an XOR gate that allows a
1-bit full adder to be implemented within an LC. In addition,
a dedicated AND gate improves the efficiency of multiplier
implementation.
The dedicated carry path can also be used to cascade function generators for implementing wide logic functions.
BUFTs
Each Virtex CLB contains two 3-state drivers (BUFTs) that
can drive on-chip busses. See Dedicated Routing, page 7.
Each Virtex BUFT has an independent 3-state control pin
and an independent input pin.
DS003-2 (v4.0) March 1, 2013
Product Specification
Block SelectRAM memory blocks are organized in columns.
All Virtex devices contain two such columns, one along
each vertical edge. These columns extend the full height of
the chip. Each memory block is four CLBs high, and consequently, a Virtex device 64 CLBs high contains 16 memory
blocks per column, and a total of 32 blocks.
Table 3 shows the amount of block SelectRAM memory that
is available in each Virtex device.
Table 3: Virtex Block SelectRAM Amounts
Device
# of Blocks
Total Block SelectRAM Bits
XCV50
8
32,768
XCV100
10
40,960
XCV150
12
49,152
XCV200
14
57,344
XCV300
16
65,536
XCV400
20
81,920
XCV600
24
98,304
XCV800
28
114,688
XCV1000
32
131,072
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Virtex™ 2.5 V Field Programmable Gate Arrays
Each block SelectRAM cell, as illustrated in Figure 6, is a
fully synchronous dual-ported 4096-bit RAM with independent control signals for each port. The data widths of the
two ports can be configured independently, providing
built-in bus-width conversion.
Table 4: Block SelectRAM Port Aspect Ratios
RAMB4_S#_S#
WEA
ENA
RSTA
CLKA
ADDRA[#:0]
DIA[#:0]
WEB
ENB
RSTB
CLKB
ADDRB[#:0]
DIB[#:0]
DOA[#:0]
Width
Depth
ADDR Bus
Data Bus
1
4096
ADDR
DATA
2
2048
ADDR
DATA
4
1024
ADDR
DATA
8
512
ADDR
DATA
16
256
ADDR
DATA
The Virtex block SelectRAM also includes dedicated routing
to provide an efficient interface with both CLBs and other
block SelectRAMs. Refer to XAPP130 for block SelectRAM
timing waveforms.
Programmable Routing Matrix
DOB[#:0]
It is the longest delay path that limits the speed of any
worst-case design. Consequently, the Virtex routing architecture and its place-and-route software were defined in a
single optimization process. This joint optimization minimizes long-path delays, and consequently, yields the best
system performance.
xcv_ds_006
Figure 6: Dual-Port Block SelectRAM
Table 4 shows the depth and width aspect ratios for the
block SelectRAM.
The joint optimization also reduces design compilation
times because the architecture is software-friendly. Design
cycles are correspondingly reduced due to shorter design
iteration times.
To Adjacent
GRM
To Adjacent
GRM
To Adjacent
GRM
GRM
To Adjacent
GRM
Direct Connection
To Adjacent
CLB
CLB
Direct Connection
To Adjacent
CLB
X8794b
Figure 7: Virtex Local Routing
Local Routing
•
The VersaBlock provides local routing resources, as shown
in Figure 7, providing the following three types of connections.
•
•
Interconnections among the LUTs, flip-flops, and GRM
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Internal CLB feedback paths that provide high-speed
connections to LUTs within the same CLB, chaining
them together with minimal routing delay
Direct paths that provide high-speed connections
between horizontally adjacent CLBs, eliminating the
delay of the GRM.
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General Purpose Routing
•
Most Virtex signals are routed on the general purpose routing, and consequently, the majority of interconnect
resources are associated with this level of the routing hierarchy. The general routing resources are located in horizontal and vertical routing channels associated with the rows
and columns CLBs. The general-purpose routing resources
are listed below.
•
•
•
Adjacent to each CLB is a General Routing Matrix
(GRM). The GRM is the switch matrix through which
horizontal and vertical routing resources connect, and
is also the means by which the CLB gains access to
the general purpose routing.
24 single-length lines route GRM signals to adjacent
GRMs in each of the four directions.
12 buffered Hex lines route GRM signals to another
GRMs six-blocks away in each one of the four
directions. Organized in a staggered pattern, Hex lines
can be driven only at their endpoints. Hex-line signals
can be accessed either at the endpoints or at the
midpoint (three blocks from the source). One third of
the Hex lines are bidirectional, while the remaining
ones are uni-directional.
12 Longlines are buffered, bidirectional wires that
distribute signals across the device quickly and
efficiently. Vertical Longlines span the full height of the
device, and horizontal ones span the full width of the
device.
I/O Routing
Virtex devices have additional routing resources around
their periphery that form an interface between the CLB array
and the IOBs. This additional routing, called the VersaRing,
facilitates pin-swapping and pin-locking, such that logic
redesigns can adapt to existing PCB layouts. Time-to-market is reduced, since PCBs and other system components
can be manufactured while the logic design is still in progress.
Dedicated Routing
Some classes of signal require dedicated routing resources
to maximize performance. In the Virtex architecture, dedicated routing resources are provided for two classes of signal.
•
•
Horizontal routing resources are provided for on-chip
3-state busses. Four partitionable bus lines are
provided per CLB row, permitting multiple busses
within a row, as shown in Figure 8.
Two dedicated nets per CLB propagate carry signals
vertically to the adjacent CLB.
Tri-State
Lines
CLB
CLB
CLB
CLB
buft_c.eps
Figure 8: BUFT Connections to Dedicated Horizontal Bus Lines
Global Routing
•
Global Routing resources distribute clocks and other signals with very high fanout throughout the device. Virtex
devices include two tiers of global routing resources
referred to as primary global and secondary local clock routing resources.
•
The primary global routing resources are four
dedicated global nets with dedicated input pins that are
designed to distribute high-fanout clock signals with
minimal skew. Each global clock net can drive all CLB,
IOB, and block RAM clock pins. The primary global
nets can only be driven by global buffers. There are
four global buffers, one for each global net.
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The secondary local clock routing resources consist of
24 backbone lines, 12 across the top of the chip and 12
across bottom. From these lines, up to 12 unique
signals per column can be distributed via the 12
longlines in the column. These secondary resources
are more flexible than the primary resources since they
are not restricted to routing only to clock pins.
Clock Distribution
Virtex provides high-speed, low-skew clock distribution
through the primary global routing resources described
above. A typical clock distribution net is shown in Figure 9.
Four global buffers are provided, two at the top center of the
device and two at the bottom center. These drive the four
primary global nets that in turn drive any clock pin.
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Four dedicated clock pads are provided, one adjacent to
each of the global buffers. The input to the global buffer is
Global Clock Rows
selected either from these pads or from signals in the general purpose routing.
GCLKPAD3
GCLKPAD2
GCLKBUF3
GCLKBUF2
Global Clock Column
Global Clock Spine
GCLKBUF1
GCLKBUF0
GCLKPAD1
GCLKPAD0
gclkbu_2.eps
Figure 9: Global Clock Distribution Network
Delay-Locked Loop (DLL)
Boundary Scan
Associated with each global clock input buffer is a fully digital Delay-Locked Loop (DLL) that can eliminate skew
between the clock input pad and internal clock-input pins
throughout the device. Each DLL can drive two global clock
networks.The DLL monitors the input clock and the distributed clock, and automatically adjusts a clock delay element.
Clock edges reach internal flip-flops one to four clock periods after they arrive at the input. This closed-loop system
effectively eliminates clock-distribution delay by ensuring
that clock edges arrive at internal flip-flops in synchronism
with clock edges arriving at the input.
Virtex devices support all the mandatory boundary-scan
instructions specified in the IEEE standard 1149.1. A Test
Access Port (TAP) and registers are provided that implement
the EXTEST, INTEST, SAMPLE/PRELOAD, BYPASS,
IDCODE, USERCODE, and HIGHZ instructions. The TAP
also supports two internal scan chains and configuration/readback of the device.The TAP uses dedicated package
pins that always operate using LVTTL. For TDO to operate
using LVTTL, the VCCO for Bank 2 should be 3.3 V. Otherwise, TDO switches rail-to-rail between ground and VCCO.
In addition to eliminating clock-distribution delay, the DLL
provides advanced control of multiple clock domains. The
DLL provides four quadrature phases of the source clock,
can double the clock, or divide the clock by 1.5, 2, 2.5, 3, 4,
5, 8, or 16.
The DLL also operates as a clock mirror. By driving the output from a DLL off-chip and then back on again, the DLL can
be used to de-skew a board level clock among multiple Virtex devices.
In order to guarantee that the system clock is operating correctly prior to the FPGA starting up after configuration, the
DLL can delay the completion of the configuration process
until after it has achieved lock.
See DLL Timing Parameters, page 21 of Module 3, for frequency range information.
Module 2 of 4
8
Boundary-scan operation is independent of individual IOB
configurations, and unaffected by package type. All IOBs,
including un-bonded ones, are treated as independent
3-state bidirectional pins in a single scan chain. Retention of
the bidirectional test capability after configuration facilitates
the testing of external interconnections, provided the user
design or application is turned off.
Table 5 lists the boundary-scan instructions supported in
Virtex FPGAs. Internal signals can be captured during
EXTEST by connecting them to un-bonded or unused IOBs.
They can also be connected to the unused outputs of IOBs
defined as unidirectional input pins.
Before the device is configured, all instructions except
USER1 and USER2 are available. After configuration, all
instructions are available. During configuration, it is recommended that those operations using the boundary-scan
register (SAMPLE/PRELOAD, INTEST, EXTEST) not be
performed.
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Virtex™ 2.5 V Field Programmable Gate Arrays
The FPGA supports up to two additional internal scan
chains that can be specified using the BSCAN macro. The
macro provides two user pins (SEL1 and SEL2) which are
decodes of the USER1 and USER2 instructions respectively. For these instructions, two corresponding pins (TDO1
and TDO2) allow user scan data to be shifted out of TDO.
In addition to the test instructions outlined above, the
boundary-scan circuitry can be used to configure the
FPGA, and also to read back the configuration data.
Figure 10 is a diagram of the Virtex Series boundary scan
logic. It includes three bits of Data Register per IOB, the
IEEE 1149.1 Test Access Port controller, and the Instruction
Register with decodes.
Likewise, there are individual clock pins (DRCK1 and
DRCK2) for each user register. There is a common input pin
(TDI) and shared output pins that represent the state of the
TAP controller (RESET, SHIFT, and UPDATE).
Instruction Set
The Virtex Series boundary scan instruction set also
includes instructions to configure the device and read back
configuration data (CFG_IN, CFG_OUT, and JSTART). The
complete instruction set is coded as shown in Table 5.
Bit Sequence
The order within each IOB is: In, Out, 3-State. The
input-only pins contribute only the In bit to the boundary
scan I/O data register, while the output-only pins contributes
all three bits.
Data Registers
The primary data register is the boundary scan register. For
each IOB pin in the FPGA, bonded or not, it includes three
bits for In, Out, and 3-State Control. Non-IOB pins have
appropriate partial bit population if input-only or output-only.
Each EXTEST CAPTURED-OR state captures all In, Out,
and 3-state pins.
From a cavity-up view of the chip (as shown in EPIC), starting in the upper right chip corner, the boundary scan
data-register bits are ordered as shown in Figure 11.
BSDL (Boundary Scan Description Language) files for Virtex Series devices are available on the Xilinx web site in the
File Download area.
The other standard data register is the single flip-flop
BYPASS register. It synchronizes data being passed
through the FPGA to the next downstream boundary scan
device.
DATA IN
IOB.T
0
1
0
IOB
IOB
IOB
IOB
IOB
sd
D
Q
D
Q
1
LE
IOB
IOB
1
sd
D
D
Q
Q
0
IOB
IOB
IOB
IOB
IOB
IOB
LE
1
IOB.I
0
1
IOB
IOB
IOB
IOB
IOB
BYPASS
REGISTER
0
sd
D
Q
D
Q
LE
1
0
IOB.Q
IOB
IOB.T
TDI
INSTRUCTION REGISTER
M TDO
U
X
0
1
0
sd
D
Q
D
Q
1
LE
1
0
sd
D
Q
D
Q
LE
1
IOB.I
0
DATAOUT
SHIFT/
CLOCK DATA
CAPTURE
REGISTER
UPDATE
EXTEST
X9016
Figure 10: Virtex Series Boundary Scan Logic
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Virtex™ 2.5 V Field Programmable Gate Arrays
Identification Registers
Bit 0 ( TDO end)
Bit 1
Bit 2
Right half of Top-edge IOBs (Right-to-Left)
GCLK2
GCLK3
The IDCODE register is supported. By using the IDCODE,
the device connected to the JTAG port can be determined.
Left half of Top-edge IOBs (Right-to-Left)
The IDCODE register has the following binary format:
Left-edge IOBs (Top-to-Bottom)
vvvv:ffff:fffa:aaaa:aaaa:cccc:cccc:ccc1
M1
M0
M2
where
v = the die version number
Left half of Bottom-edge IOBs (Left-to-Right)
f = the family code (03h for Virtex family)
GCLK1
GCLK0
Right half of Bottom-edge IOBs (Left-to-Right)
a = the number of CLB rows (ranges from 010h for XCV50
to 040h for XCV1000)
DONE
PROG
c = the company code (49h for Xilinx)
The USERCODE register is supported. By using the USERCODE, a user-programmable identification code can be
loaded and shifted out for examination. The identification
code is embedded in the bitstream during bitstream generation and is valid only after configuration.
Right-edge IOBs (Bottom -to-Top)
(TDI end)
CCLK
990602001
Figure 11: Boundary Scan Bit Sequence
Table 6: IDCODEs Assigned to Virtex FPGAs
Table 5: Boundary Scan Instructions
FPGA
IDCODE
Description
XCV50
v0610093h
00000
Enables boundary-scan
EXTEST operation
XCV100
v0614093h
00001
Enables boundary-scan
SAMPLE/PRELOAD
operation
XCV150
v0618093h
XCV200
v061C093h
XCV300
v0620093h
XCV400
v0628093h
XCV600
v0630093h
XCV800
v0638093h
XCV1000
v0640093h
Boundary-Scan
Command
Binary
Code(4:0)
EXTEST
SAMPLE/PRELOAD
USER 1
00010
Access user-defined
register 1
USER 2
00011
Access user-defined
register 2
CFG_OUT
00100
Access the configuration
bus for read operations.
CFG_IN
00101
Access the configuration
bus for write operations.
Including Boundary Scan in a Design
INTEST
00111
Enables boundary-scan
INTEST operation
USERCODE
01000
Enables shifting out
USER code
Since the boundary scan pins are dedicated, no special element needs to be added to the design unless an internal
data register (USER1 or USER2) is desired.
IDCODE
01001
Enables shifting out of ID
Code
HIGHZ
01010
3-states output pins while
enabling the Bypass
Register
JSTART
01100
Clock the start-up
sequence when
StartupClk is TCK
BYPASS
11111
Enables BYPASS
Virtex FPGAs are supported by the Xilinx Foundation and
Alliance CAE tools. The basic methodology for Virtex
design consists of three interrelated steps: design entry,
implementation, and verification. Industry-standard tools
are used for design entry and simulation (for example, Synopsys FPGA Express), while Xilinx provides proprietary
architecture-specific tools for implementation.
RESERVED
All other
codes
Xilinx reserved
instructions
The Xilinx development system is integrated under the
Xilinx Design Manager (XDM™) software, providing design-
Module 2 of 4
10
If an internal data register is used, insert the boundary scan
symbol and connect the necessary pins as appropriate.
Development System
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Virtex™ 2.5 V Field Programmable Gate Arrays
ers with a common user interface regardless of their choice
of entry and verification tools. The XDM software simplifies
the selection of implementation options with pull-down
menus and on-line help.
design, thus allowing the most convenient entry method to
be used for each portion of the design.
Application programs ranging from schematic capture to
Placement and Routing (PAR) can be accessed through the
XDM software. The program command sequence is generated prior to execution, and stored for documentation.
The place-and-route tools (PAR) automatically provide the
implementation flow described in this section. The partitioner takes the EDIF net list for the design and maps the
logic into the architectural resources of the FPGA (CLBs
and IOBs, for example). The placer then determines the
best locations for these blocks based on their interconnections and the desired performance. Finally, the router interconnects the blocks.
Several advanced software features facilitate Virtex design.
RPMs, for example, are schematic-based macros with relative location constraints to guide their placement. They help
ensure optimal implementation of common functions.
For HDL design entry, the Xilinx FPGA Foundation development system provides interfaces to the following synthesis
design environments.
•
•
•
Synopsys (FPGA Compiler, FPGA Express)
Exemplar (Spectrum)
Synplicity (Synplify)
For schematic design entry, the Xilinx FPGA Foundation
and alliance development system provides interfaces to the
following schematic-capture design environments.
•
•
Mentor Graphics V8 (Design Architect, QuickSim II)
Viewlogic Systems (Viewdraw)
Third-party vendors support many other environments.
A standard interface-file specification, Electronic Design
Interchange Format (EDIF), simplifies file transfers into and
out of the development system.
Virtex FPGAs supported by a unified library of standard
functions. This library contains over 400 primitives and macros, ranging from 2-input AND gates to 16-bit accumulators,
and includes arithmetic functions, comparators, counters,
data registers, decoders, encoders, I/O functions, latches,
Boolean functions, multiplexers, shift registers, and barrel
shifters.
The “soft macro” portion of the library contains detailed
descriptions of common logic functions, but does not contain any partitioning or placement information. The performance of these macros depends, therefore, on the
partitioning and placement obtained during implementation.
RPMs, on the other hand, do contain predetermined partitioning and placement information that permits optimal
implementation of these functions. Users can create their
own library of soft macros or RPMs based on the macros
and primitives in the standard library.
The design environment supports hierarchical design entry,
with high-level schematics that comprise major functional
blocks, while lower-level schematics define the logic in
these blocks. These hierarchical design elements are automatically combined by the implementation tools. Different
design entry tools can be combined within a hierarchical
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Design Implementation
The PAR algorithms support fully automatic implementation
of most designs. For demanding applications, however, the
user can exercise various degrees of control over the process. User partitioning, placement, and routing information
is optionally specified during the design-entry process. The
implementation of highly structured designs can benefit
greatly from basic floor planning.
The implementation software incorporates Timing Wizard®
timing-driven placement and routing. Designers specify timing requirements along entire paths during design entry.
The timing path analysis routines in PAR then recognize
these user-specified requirements and accommodate them.
Timing requirements are entered on a schematic in a form
directly relating to the system requirements, such as the targeted clock frequency, or the maximum allowable delay
between two registers. In this way, the overall performance
of the system along entire signal paths is automatically tailored to user-generated specifications. Specific timing information for individual nets is unnecessary.
Design Verification
In addition to conventional software simulation, FPGA users
can use in-circuit debugging techniques. Because Xilinx
devices are infinitely reprogrammable, designs can be verified in real time without the need for extensive sets of software simulation vectors.
The development system supports both software simulation
and in-circuit debugging techniques. For simulation, the
system extracts the post-layout timing information from the
design database, and back-annotates this information into
the net list for use by the simulator. Alternatively, the user
can verify timing-critical portions of the design using the
TRACE® static timing analyzer.
For in-circuit debugging, the development system includes
a download and readback cable. This cable connects the
FPGA in the target system to a PC or workstation. After
downloading the design into the FPGA, the designer can
single-step the logic, readback the contents of the flip-flops,
and so observe the internal logic state. Simple modifications can be downloaded into the system in a matter of minutes.
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Configuration
Virtex devices are configured by loading configuration data
into the internal configuration memory. Some of the pins
used for this are dedicated configuration pins, while others
can be re-used as general purpose inputs and outputs once
configuration is complete.
The following are dedicated pins:
•
•
•
•
•
After Virtex devices are configured, unused IOBs function
as 3-state OBUFTs with weak pull downs. For a more
detailed description than that given below, see the
XAPP138, Virtex Configuration and Readback.
Configuration Modes
Virtex supports the following four configuration modes.
•
•
•
•
Mode pins (M2, M1, M0)
Configuration clock pin (CCLK)
PROGRAM pin
DONE pin
Boundary-scan pins (TDI, TDO, TMS, TCK)
Depending on the configuration mode chosen, CCLK can
be an output generated by the FPGA, or it can be generated
externally and provided to the FPGA as an input. The
PROGRAM pin must be pulled High prior to reconfiguration.
Note that some configuration pins can act as outputs. For
correct operation, these pins can require a VCCO of 3.3 V to
permit LVTTL operation. All the pins affected are in banks 2
or 3. The configuration pins needed for SelectMap (CS,
Write) are located in bank 1.
Slave-serial mode
Master-serial mode
SelectMAP mode
Boundary-scan mode
The Configuration mode pins (M2, M1, M0) select among
these configuration modes with the option in each case of
having the IOB pins either pulled up or left floating prior to
configuration. The selection codes are listed in Table 7.
Configuration through the boundary-scan port is always
available, independent of the mode selection. Selecting the
boundary-scan mode simply turns off the other modes. The
three mode pins have internal pull-up resistors, and default
to a logic High if left unconnected. However, it is recommended to drive the configuration mode pins externally.
Table 7: Configuration Codes
Configuration Mode
M2
M1
M0
CCLK Direction
Data Width
Serial Dout
Configuration Pull-ups
Master-serial mode
0
0
0
Out
1
Yes
No
Boundary-scan mode
1
0
1
N/A
1
No
No
SelectMAP mode
1
1
0
In
8
No
No
Slave-serial mode
1
1
1
In
1
Yes
No
Master-serial mode
1
0
0
Out
1
Yes
Yes
Boundary-scan mode
0
0
1
N/A
1
No
Yes
SelectMAP mode
0
1
0
In
8
No
Yes
Slave-serial mode
0
1
1
In
1
Yes
Yes
Slave-Serial Mode
In slave-serial mode, the FPGA receives configuration data
in bit-serial form from a serial PROM or other source of
serial configuration data. The serial bitstream must be setup
at the DIN input pin a short time before each rising edge of
an externally generated CCLK.
For more information on serial PROMs, see the PROM data
sheet at:
http://www.xilinx.com/bvdocs/publications/ds026.pdf.
Multiple FPGAs can be daisy-chained for configuration from a
single source. After a particular FPGA has been configured,
the data for the next device is routed to the DOUT pin. The
data on the DOUT pin changes on the rising edge of CCLK.
The change of DOUT on the rising edge of CCLK differs
from previous families, but does not cause a problem for
Module 2 of 4
12
mixed configuration chains. This change was made to
improve serial configuration rates for Virtex-only chains.
Figure 12 shows a full master/slave system. A Virtex device
in slave-serial mode should be connected as shown in the
third device from the left.
Slave-serial mode is selected by applying or
to the mode pins (M2, M1, M0). A weak pull-up on the mode
pins makes slave-serial the default mode if the pins are left
unconnected. However, it is recommended to drive the configuration mode pins externally. Figure 13 shows
slave-serial mode programming switching characteristics.
Table 8 provides more detail about the characteristics
shown in Figure 13. Configuration must be delayed until the
INIT pins of all daisy-chained FPGAs are High.
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Virtex™ 2.5 V Field Programmable Gate Arrays
Table 8: Master/Slave Serial Mode Programming Switching
Figure
References
Symbol
Values
Units
DIN setup/hold, slave mode
1/2
TDCC/TCCD
5.0 / 0
ns, min
DIN setup/hold, master mode
1/2
TDSCK/TCKDS
5.0 / 0
ns, min
DOUT
3
TCCO
12.0
ns, max
High time
4
TCCH
5.0
ns, min
Low time
5
TCCL
5.0
ns, min
FCC
66
MHz, max
Description
CCLK
Maximum Frequency
Frequency Tolerance, master mode with
respect to nominal
+45%
–30%
VCC
3.3V
330 Ω
M0 M1
M0 M1
M2
M2
DOUT
Optional Pull-up
1
Resistor on Done
DIN
DOUT
CCLK
VIRTEX
MASTER
SERIAL
CCLK
DIN
PROGRAM
DONE
INIT
XC1701L
CLK
DATA
CEO
CE
RESET/OE
VIRTEX,
XC4000XL,
SLAVE
PROGRAM
INIT
DONE
(Low Reset Option Used)
PROGRAM
Note 1: If none of the Virtex FPGAs have been selected to drive DONE, an external pull-up resistor
of 330 Ω should be added to the common DONE line. (For Spartan-XL devices, add a 4.7K Ω
pull-up resistor.) This pull-up is not needed if the DriveDONE attribute is set. If used,
DriveDONE should be selected only for the last device in the configuration chain.
xcv_12_050103
Figure 12: Master/Slave Serial Mode Circuit Diagram
DIN
1 TDCC
2 TCCD
5 TCCL
CCLK
4 TCCH
3 TCCO
DOUT
(Output)
X5379_a
Figure 13: Slave-Serial Mode Programming Switching Characteristics
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Master-Serial Mode
In master-serial mode, the CCLK output of the FPGA drives
a Xilinx Serial PROM that feeds bit-serial data to the DIN
input. The FPGA accepts this data on each rising CCLK
edge. After the FPGA has been loaded, the data for the next
device in a daisy-chain is presented on the DOUT pin after
the rising CCLK edge.
daisy-chained FPGAs are fast enough to support the clock
rate.
On power-up, the CCLK frequency is 2.5 MHz. This frequency is used until the ConfigRate bits have been loaded
when the frequency changes to the selected ConfigRate.
Unless a different frequency is specified in the design, the
default ConfigRate is 4 MHz.
The interface is identical to slave-serial except that an internal oscillator is used to generate the configuration clock
(CCLK). A wide range of frequencies can be selected for
CCLK which always starts at a slow default frequency. Configuration bits then switch CCLK to a higher frequency for
the remainder of the configuration. Switching to a lower frequency is prohibited.
Figure 12 shows a full master/slave system. In this system,
the left-most device operates in master-serial mode. The
remaining devices operate in slave-serial mode. The
SPROM RESET pin is driven by INIT, and the CE input is
driven by DONE. There is the potential for contention on the
DONE pin, depending on the start-up sequence options
chosen.
The CCLK frequency is set using the ConfigRate option in
the bitstream generation software. The maximum CCLK frequency that can be selected is 60 MHz. When selecting a
CCLK frequency, ensure that the serial PROM and any
Figure 14 shows the timing of master-serial configuration.
Master-serial mode is selected by a or on the
mode pins (M2, M1, M0). Table 8 shows the timing information for Figure 14.
CCLK
(Output)
TCKDS 2
1 TDSCK
Serial Data In
Serial DOUT
(Output)
DS022_44_071201
Figure 14: Master-Serial Mode Programming Switching Characteristics
At power-up, VCC must rise from 1.0 V to VCC min in less
than 50 ms, otherwise delay configuration by pulling
PROGRAM Low until VCC is valid.
The sequence of operations necessary to configure a Virtex
FPGA serially appears in Figure 15.
SelectMAP Mode
The SelectMAP mode is the fastest configuration option.
Byte-wide data is written into the FPGA with a BUSY flag
controlling the flow of data.
An external data source provides a byte stream, CCLK, a
Chip Select (CS) signal and a Write signal (WRITE). If
BUSY is asserted (High) by the FPGA, the data must be
held until BUSY goes Low.
Data can also be read using the SelectMAP mode. If
WRITE is not asserted, configuration data is read out of the
FPGA as part of a readback operation.
Module 2 of 4
14
In the SelectMAP mode, multiple Virtex devices can be
chained in parallel. DATA pins (D7:D0), CCLK, WRITE,
BUSY, PROGRAM, DONE, and INIT can be connected in
parallel between all the FPGAs. Note that the data is organized with the MSB of each byte on pin DO and the LSB of
each byte on D7. The CS pins are kept separate, insuring
that each FPGA can be selected individually. WRITE should
be Low before loading the first bitstream and returned High
after the last device has been programmed. Use CS to
select the appropriate FPGA for loading the bitstream and
sending the configuration data. at the end of the bitstream,
deselect the loaded device and select the next target FPGA
by setting its CS pin High. A free-running oscillator or other
externally generated signal can be used for CCLK. The
BUSY signal can be ignored for frequencies below 50 MHz.
For details about frequencies above 50 MHz, see
XAPP138, Virtex Configuration and Readback. Once all the
devices have been programmed, the DONE pin goes High.
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Virtex™ 2.5 V Field Programmable Gate Arrays
Apply Power
FPGA starts to clear
configuration memory.
Set PROGRAM = High
FPGA makes a final
clearing pass and releases
INIT when finished.
If used to delay
configuration
Release INIT
INIT?
Low
High
Load a Configuration Bit
Once per bitstream,
FPGA checks data using CRC
and pulls INIT Low on error.
End of
Bitstream?
If no CRC errors found,
FPGA enters start-up phase
causing DONE to go High.
No
Yes
Configuration Completed
ds003_154_111799
Figure 15: Serial Configuration Flowchart
After configuration, the pins of the SelectMAP port can be
used as additional user I/O. Alternatively, the port can be
retained to permit high-speed 8-bit readback.
Retention of the SelectMAP port is selectable on a
design-by-design basis when the bitstream is generated. If
retention is selected, PROHIBIT constraints are required to
prevent the SelectMAP-port pins from being used as user
I/O.
Multiple Virtex FPGAs can be configured using the SelectMAP mode, and be made to start-up simultaneously. To
configure multiple devices in this way, wire the individual
CCLK, Data, WRITE, and BUSY pins of all the devices in
parallel. The individual devices are loaded separately by
asserting the CS pin of each device in turn and writing the
appropriate data. See Table 9 for SelectMAP Write Timing
Characteristics.
.
Table 9: SelectMAP Write Timing Characteristics
Description
CCLK
Symbol
Units
D0-7 Setup/Hold
1/2
TSMDCC/TSMCCD
5.0 / 1.7
ns, min
CS Setup/Hold
3/4
TSMCSCC/TSMCCCS
7.0 / 1.7
ns, min
WRITE Setup/Hold
5/6
TSMCCW/TSMWCC
7.0 / 1.7
ns, min
7
TSMCKBY
12.0
ns, max
FCC
66
MHz, max
FCCNH
50
MHz, max
BUSY Propagation Delay
Maximum Frequency
Maximum Frequency with no handshake
Write
Write operations send packets of configuration data into the
FPGA. The sequence of operations for a multi-cycle write
operation is shown below. Note that a configuration packet
can be split into many such sequences. The packet does
not have to complete within one assertion of CS, illustrated
in Figure 16.
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1. Assert WRITE and CS Low. Note that when CS is
asserted on successive CCLKs, WRITE must remain
either asserted or de-asserted. Otherwise an abort will
be initiated, as described below.
2. Drive data onto D[7:0]. Note that to avoid contention,
the data source should not be enabled while CS is Low
and WRITE is High. Similarly, while WRITE is High, no
more that one CS should be asserted.
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5. De-assert CS and WRITE.
3. At the rising edge of CCLK: If BUSY is Low, the data is
accepted on this clock. If BUSY is High (from a previous
write), the data is not accepted. Acceptance will instead
occur on the first clock after BUSY goes Low, and the
data must be held until this has happened.
A flowchart for the write operation appears in Figure 17.
Note that if CCLK is slower than fCCNH, the FPGA never
asserts BUSY. In this case, the above handshake is unnecessary, and data can simply be entered into the FPGA every
CCLK cycle.
4. Repeat steps 2 and 3 until all the data has been sent.
CCLK
CS
WRITE
3
4
5
6
1
2
DATA[0:7]
7
BUSY
Write
Write
No Write
Write
ds003_16_071902
Figure 16: Write Operations
Module 2 of 4
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Apply Power
FPGA starts to clear
configuration memory.
PROGRAM
from Low
to High
FPGA makes a final
clearing pass and releases
INIT when finished.
No
Yes
If used to delay
configuration
Release INIT
INIT?
Low
High
Set WRITE = Low
Enter Data Source
Sequence A
On first FPGA
Set CS = Low
Apply Configuration Byte
Once per bitstream,
FPGA checks data using CRC
and pulls INIT Low on error.
Busy?
High
Low
End of Data?
If no errors,
first FPGAs enter start-up phase
releasing DONE.
No
Yes
Set CS = High
If no errors,
later FPGAs enter start-up phase
releasing DONE.
Repeat Sequence A
On first FPGA
For any other FPGAs
Disable Data Source
Set WRITE = High
When all DONE pins
are released, DONE goes High
and start-up sequences complete.
Configuration Completed
ds003_17_090602
Figure 17: SelectMAP Flowchart for Write Operation
Abort
During a given assertion of CS, the user cannot switch from
a write to a read, or vice-versa. This action causes the current packet command to be aborted. The device will remain
BUSY until the aborted operation has completed. Following
an abort, data is assumed to be unaligned to word boundar-
DS003-2 (v4.0) March 1, 2013
Product Specification
ies, and the FPGA requires a new synchronization word
prior to accepting any new packets.
To initiate an abort during a write operation, de-assert
WRITE. At the rising edge of CCLK, an abort is initiated, as
shown in Figure 18.
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The end of the memory-clearing phase is signalled by INIT
going High, and the completion of the entire process is signalled by DONE going High.
CCLK
The power-up timing of configuration signals is shown in
Figure 19. The corresponding timing characteristics are
listed in Table 10.
CS
WRITE
VCC
TPOR
DATA[0:7]
PROGRAM
BUSY
TPI
INIT
Abort
X8797_c
TICCK
CCLK OUTPUT or INPUT
Figure 18: SelectMAP Write Abort Waveforms
M0, M1, M2
VALID
(Required)
Boundary-Scan Mode
98122302
In the boundary-scan mode, configuration is done through
the IEEE 1149.1 Test Access Port. Note that the
PROGRAM pin must be pulled High prior to reconfiguration.
A Low on the PROGRAM pin resets the TAP controller and
no JTAG operations can be performed.
Configuration through the TAP uses the CFG_IN instruction. This instruction allows data input on TDI to be converted into data packets for the internal configuration bus.
The following steps are required to configure the FPGA
through the boundary-scan port (when using TCK as a
start-up clock).
1. Load the CFG_IN instruction into the boundary-scan
instruction register (IR)
Figure 19: Power-Up Timing Configuration Signals
Table 10: Power-up Timing Characteristics
Description
Symbol
Value
Units
Power-on Reset
TPOR
2.0
ms, max
Program Latency
TPL
100.0
μs, max
TICCK
0.5
μs, min
4.0
μs, max
300
ns, min
CCLK (output) Delay
Program Pulse Width
TPROGRAM
Delaying Configuration
7. Clock TCK through the startup sequence
INIT can be held Low using an open-drain driver. An
open-drain is required since INIT is a bidirectional
open-drain pin that is held Low by the FPGA while the configuration memory is being cleared. Extending the time that
the pin is Low causes the configuration sequencer to wait.
Thus, configuration is delayed by preventing entry into the
phase where data is loaded.
8. Return to RTI
Start-Up Sequence
Configuration and readback via the TAP is always available.
The boundary-scan mode is selected by a or 001>
on the mode pins (M2, M1, M0). For details on TAP characteristics, refer to XAPP139.
The default Start-up sequence is that one CCLK cycle after
DONE goes High, the global 3-state signal (GTS) is released.
This permits device outputs to turn on as necessary.
2. Enter the Shift-DR (SDR) state
3. Shift a configuration bitstream into TDI
4. Return to Run-Test-Idle (RTI)
5. Load the JSTART instruction into IR
6. Enter the SDR state
Configuration Sequence
The configuration of Virtex devices is a three-phase process. First, the configuration memory is cleared. Next, configuration data is loaded into the memory, and finally, the
logic is activated by a start-up process.
Configuration is automatically initiated on power-up unless
it is delayed by the user, as described below. The configuration process can also be initiated by asserting PROGRAM.
Module 2 of 4
18
One CCLK cycle later, the Global Set/Reset (GSR) and
Global Write Enable (GWE) signals are released. This permits the internal storage elements to begin changing state
in response to the logic and the user clock.
The relative timing of these events can be changed. In addition, the GTS, GSR, and GWE events can be made dependent on the DONE pins of multiple devices all going High,
forcing the devices to start in synchronism. The sequence
can also be paused at any stage until lock has been
achieved on any or all DLLs.
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Data Stream Format
Readback
Virtex devices are configured by sequentially loading
frames of data. Table 11 lists the total number of bits
required to configure each device. For more detailed information, see application note XAPP151 “Virtex Configuration Architecture Advanced Users Guide”.
The configuration data stored in the Virtex configuration
memory can be readback for verification. Along with the
configuration data it is possible to readback the contents all
flip-flops/latches, LUTRAMs, and block RAMs. This capability is used for real-time debugging.
Table 11: Virtex Bit-Stream Lengths
Device
# of Configuration Bits
XCV50
559,200
XCV100
781,216
XCV150
1,040,096
XCV200
1,335,840
XCV300
1,751,808
XCV400
2,546,048
XCV600
3,607,968
XCV800
4,715,616
XCV1000
6,127,744
For more detailed information, see Application Note
XAPP138: Virtex FPGA Series Configuration and Readback,
available online at www.xilinx.com.
Revision History
Date
Version
11/98
1.0
Initial Xilinx release.
01/99
1.2
Updated package drawings and specs.
02/99
1.3
Update of package drawings, updated specifications.
05/99
1.4
Addition of package drawings and specifications.
05/99
1.5
Replaced FG 676 & FG680 package drawings.
07/99
1.6
Changed Boundary Scan Information and changed Figure 11, Boundary Scan Bit
Sequence. Updated IOB Input & Output delays. Added Capacitance info for different I/O
Standards. Added 5 V tolerant information. Added DLL Parameters and waveforms and
new Pin-to-pin Input and Output Parameter tables for Global Clock Input to Output and
Setup and Hold. Changed Configuration Information including Figures 12, 14, 17 & 19.
Added device-dependent listings for quiescent currents ICCINTQ and ICCOQ. Updated
IOB Input and Output Delays based on default standard of LVTTL, 12 mA, Fast Slew Rate.
Added IOB Input Switching Characteristics Standard Adjustments.
09/99
1.7
Speed grade update to preliminary status, Power-on specification and Clock-to-Out
Minimums additions, “0” hold time listing explanation, quiescent current listing update, and
Figure 6 ADDRA input label correction. Added TIJITCC parameter, changed TOJIT to TOPHASE.
01/00
1.8
Update to speed.txt file 1.96. Corrections for CRs 111036,111137, 112697, 115479,
117153, 117154, and 117612. Modified notes for Recommended Operating Conditions
(voltage and temperature). Changed Bank information for VCCO in CS144 package on p.43.
DS003-2 (v4.0) March 1, 2013
Product Specification
Revision
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Date
Version
Revision
01/00
1.9
Updated DLL Jitter Parameter table and waveforms, added Delay Measurement
Methodology table for different I/O standards, changed buffered Hex line info and
Input/Output Timing measurement notes.
03/00
2.0
New TBCKO values; corrected FG680 package connection drawing; new note about status
of CCLK pin after configuration.
05/00
2.1
Modified “Pins not listed...” statement. Speed grade update to Final status.
05/00
2.2
Modified Table 18.
09/00
2.3
•
•
•
Added XCV400 values to table under Minimum Clock-to-Out for Virtex Devices.
Corrected Units column in table under IOB Input Switching Characteristics.
Added values to table under CLB SelectRAM Switching Characteristics.
10/00
2.4
•
•
Corrected Pinout information for devices in the BG256, BG432, and BG560 packages in
Table 18.
Corrected BG256 Pin Function Diagram.
04/01
2.5
•
•
•
Revised minimums for Global Clock Set-Up and Hold for LVTTL Standard, with DLL.
Updated SelectMAP Write Timing Characteristics values in Table 9.
Converted file to modularized format. See the Virtex Data Sheet section.
07/19/01
2.6
•
Made minor edits to text under Configuration.
07/19/02
2.7
•
Made minor edit to Figure 16 and Figure 18.
09/10/02
2.8
•
Added clarifications in the Configuration, Boundary-Scan Mode, and Block
SelectRAM sections. Revised Figure 17.
12/09/02
2.8.1
•
•
Added clarification in the Boundary Scan section.
Corrected number of buffered Hex lines listed in General Purpose Routing section.
03/01/13
4.0
The products listed in this data sheet are obsolete. See XCN10016 for further information.
Virtex Data Sheet
The Virtex Data Sheet contains the following modules:
•
DS003-1, Virtex 2.5V FPGAs:
Introduction and Ordering Information (Module 1)
•
DS003-3, Virtex 2.5V FPGAs:
DC and Switching Characteristics (Module 3)
•
DS003-2, Virtex 2.5V FPGAs:
Functional Description (Module 2)
•
DS003-4, Virtex 2.5V FPGAs:
Pinout Tables (Module 4)
Module 2 of 4
20
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Virtex™ 2.5 V
Field Programmable Gate Arrays
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Production Product Specification
Virtex Electrical Characteristics
Definition of Terms
Electrical and switching characteristics are specified on a
per-speed-grade basis and can be designated as Advance,
Preliminary, or Production. Each designation is defined as
follows:
Advance: These speed files are based on simulations only
and are typically available soon after device design specifications are frozen. Although speed grades with this designation are considered relatively stable and conservative,
some under-reporting might still occur.
Preliminary: These speed files are based on complete ES
(engineering sample) silicon characterization. Devices and
speed grades with this designation are intended to give a
better indication of the expected performance of production
silicon. The probability of under-reporting delays is greatly
reduced as compared to Advance data.
Production: These speed files are released once enough
production silicon of a particular device family member has
been characterized to provide full correlation between
speed files and devices over numerous production lots.
There is no under-reporting of delays, and customers
receive formal notification of any subsequent changes. Typically, the slowest speed grades transition to Production
before faster speed grades.
Table 1 correlates the current status of each Virtex device
with a corresponding speed file designation.
Table 1: Virtex Device Speed Grade Designations
Speed Grade Designations
Device
Advance
Preliminary
Production
XCV50
–6, –5, –4
XCV100
–6, –5, –4
XCV150
–6, –5, –4
XCV200
–6, –5, –4
XCV300
–6, –5, –4
XCV400
–6, –5, –4
XCV600
–6, –5, –4
XCV800
–6, –5, –4
XCV1000
–6, –5, –4
All specifications are subject to change without notice.
All specifications are representative of worst-case supply
voltage and junction temperature conditions. The parameters included are common to popular designs and typical
applications. Contact the factory for design considerations
requiring more detailed information.
© 1999-2013 Xilinx, Inc. All rights reserved. All Xilinx trademarks, registered trademarks, patents, and disclaimers are as listed at http://www.xilinx.com/legal.htm.
All other trademarks and registered trademarks are the property of their respective owners. All specifications are subject to change without notice.
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Virtex DC Characteristics
Absolute Maximum Ratings
Description(1)
Symbol
Units
VCCINT
Supply voltage relative to GND (2)
–0.5 to 3.0
V
VCCO
Supply voltage relative to GND (2)
–0.5 to 4.0
V
VREF
Input Reference Voltage
–0.5 to 3.6
V
Using VREF
–0.5 to 3.6
V
Internal threshold
–0.5 to 5.5
V
–0.5 to 5.5
V
50
ms
–65 to +150
°C
+125
°C
Input voltage relative to GND (3)
VIN
VTS
Voltage applied to 3-state output
VCC
Longest Supply Voltage Rise Time from 1V-2.375V
TSTG
Storage temperature (ambient)
TJ
Junction temperature(4)
Plastic Packages
Notes:
1. Stresses beyond those listed under Absolute Maximum Ratings can cause permanent damage to the device. These are stress
ratings only, and functional operation of the device at these or any other conditions beyond those listed under Operating Conditions
is not implied. Exposure to Absolute Maximum Ratings conditions for extended periods of time can affect device reliability.
2. Power supplies can turn on in any order.
3. For protracted periods (e.g., longer than a day), VIN should not exceed VCCO by more than 3.6 V.
4. For soldering guidelines and thermal considerations, see the "Device Packaging" information on www.xilinx.com.
Recommended Operating Conditions
Symbol
VCCINT (1)
VCCO (4)
TIN
Description
Min
Max
Units
Input Supply voltage relative to GND, TJ = 0 °C to +85°C
Commercial
2.5 – 5%
2.5 + 5%
V
Input Supply voltage relative to GND, TJ = –40°C to +100°C
Industrial
2.5 – 5%
2.5 + 5%
V
Supply voltage relative to GND, TJ = 0 °C to +85°C
Commercial
1.4
3.6
V
Supply voltage relative to GND, TJ = –40°C to +100°C
Industrial
1.4
3.6
V
250
ns
Input signal transition time
Notes:
1. Correct operation is guaranteed with a minimum VCCINT of 2.375 V (Nominal VCCINT –5%). Below the minimum value, all delay
parameters increase by 3% for each 50-mV reduction in VCCINT below the specified range.
2. At junction temperatures above those listed as Operating Conditions, delay parameters do increase. Please refer to the TRCE report.
3. Input and output measurement threshold is ~50% of VCC.
4. Min and Max values for VCCO are I/O Standard dependant.
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Virtex™ 2.5 V Field Programmable Gate Arrays
DC Characteristics Over Recommended Operating Conditions
Symbol
VDRINT
VDRIO
ICCINTQ
ICCOQ
IREF
IL
Description
Data Retention VCCINT Voltage
(below which configuration data can be lost)
Data Retention VCCO Voltage
(below which configuration data can be lost)
Quiescent VCCINT supply current (1,3)
Device
Min
Max
Units
All
2.0
V
All
1.2
V
XCV50
50
mA
XCV100
50
mA
XCV150
50
mA
XCV200
75
mA
XCV300
75
mA
XCV400
75
mA
XCV600
100
mA
XCV800
100
mA
XCV1000
100
mA
XCV50
2
mA
XCV100
2
mA
XCV150
2
mA
XCV200
2
mA
XCV300
2
mA
XCV400
2
mA
XCV600
2
mA
XCV800
2
mA
XCV1000
2
mA
VREF current per VREF pin
All
20
μA
Input or output leakage current
All
+10
μA
8
pF
Note (2)
0.25
mA
Note (2)
0.15
mA
Quiescent VCCO supply current (1)
BGA, PQ, HQ, packages
CIN
Input capacitance (sample tested)
IRPU
Pad pull-up (when selected) @ Vin = 0 V, VCCO = 3.3 V (sample
tested)
IRPD
Pad pull-down (when selected) @ Vin = 3.6 V (sample tested)
–10
All
All
Notes:
1. With no output current loads, no active input pull-up resistors, all I/O pins 3-stated and floating.
2. Internal pull-up and pull-down resistors guarantee valid logic levels at unconnected input pins. These pull-up and pull-down resistors
do not guarantee valid logic levels when input pins are connected to other circuits.
3. Multiply ICCINTQ limit by two for industrial grade.
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Power-On Power Supply Requirements
Xilinx FPGAs require a certain amount of supply current during power-on to insure proper device operation. The actual
current consumed depends on the power-on ramp rate of the power supply. This is the time required to reach the nominal
power supply voltage of the device (1) from 0 V. The current is highest at the fastest suggested ramp rate (0 V to nominal
voltage in 2 ms) and is lowest at the slowest allowed ramp rate (0 V to nominal voltage in 50 ms). For more details on power
supply requirements, see Application Note XAPP158 on www.xilinx.com.
Description (2)
Current Requirement (1,3)
Virtex Family, Commercial Grade
Minimum required current supply
500 mA
Virtex Family, Industrial Grade
Minimum required current supply
2A
Product
Notes:
1. Ramp rate used for this specification is from 0 - 2.7 VDC. Peak current occurs on or near the internal power-on reset threshold of
1.0V and lasts for less than 3 ms.
2. Devices are guaranteed to initialize properly with the minimum current available from the power supply as noted above.
3. Larger currents can result if ramp rates are forced to be faster.
DC Input and Output Levels
Values for VIL and VIH are recommended input voltages. Values for IOL and IOH are guaranteed output currents over the
recommended operating conditions at the VOL and VOH test points. Only selected standards are tested. These are chosen
to ensure that all standards meet their specifications. The selected standards are tested at minimum VCCO for each standard
with the respective VOL and VOH voltage levels shown. Other standards are sample tested.
Input/Output
Standard
VIH
VIL
VOL
VOH
IOL
IOH
V, min
V, max
V, min
V, max
V, Max
V, Min
mA
mA
LVTTL (1)
– 0.5
0.8
2.0
5.5
0.4
2.4
24
–24
LVCMOS2
– 0.5
.7
1.7
5.5
0.4
1.9
12
–12
PCI, 3.3 V
– 0.5
44% VCCINT
60% VCCINT
VCCO + 0.5
10% VCCO
90% VCCO
Note 2
Note 2
PCI, 5.0 V
– 0.5
0.8
2.0
5.5
0.55
2.4
Note 2
Note 2
GTL
– 0.5
VREF – 0.05
VREF + 0.05
3.6
0.4
n/a
40
n/a
GTL+
– 0.5
VREF – 0.1
VREF + 0.1
3.6
0.6
n/a
36
n/a
HSTL I (3)
– 0.5
VREF – 0.1
VREF + 0.1
3.6
0.4
VCCO – 0.4
8
–8
HSTL III
– 0.5
VREF – 0.1
VREF + 0.1
3.6
0.4
VCCO – 0.4
24
–8
HSTL IV
– 0.5
VREF – 0.1
VREF + 0.1
3.6
0.4
VCCO – 0.4
48
–8
SSTL3 I
– 0.5
VREF – 0.2
VREF + 0.2
3.6
VREF – 0.6
VREF + 0.6
8
–8
SSTL3 II
– 0.5
VREF – 0.2
VREF + 0.2
3.6
VREF – 0.8
VREF + 0.8
16
–16
SSTL2 I
– 0.5
VREF – 0.2
VREF + 0.2
3.6
VREF – 0.61
VREF + 0.61
7.6
–7.6
SSTL2 II
– 0.5
VREF – 0.2
VREF + 0.2
3.6
VREF – 0.80
VREF + 0.80
15.2
–15.2
CTT
– 0.5
VREF – 0.2
VREF + 0.2
3.6
VREF – 0.4
VREF + 0.4
8
–8
AGP
– 0.5
VREF – 0.2
VREF + 0.2
3.6
10% VCCO
90% VCCO
Note 2
Note 2
Notes:
1. VOL and VOH for lower drive currents are sample tested.
2. Tested according to the relevant specifications.
3. DC input and output levels for HSTL18 (HSTL I/O standard with VCCO of 1.8 V) are provided in an HSTL white paper on
www.xilinx.com.
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Virtex™ 2.5 V Field Programmable Gate Arrays
Virtex Switching Characteristics
All devices are 100% functionally tested. Internal timing
parameters are derived from measuring internal test patterns. Listed below are representative values. For more
specific, more precise, and worst-case guaranteed data,
use the values reported by the static timing analyzer (TRCE
in the Xilinx Development System) and back-annotated to
the simulation net list. All timing parameters assume
worst-case operating conditions (supply voltage and junction temperature). Values apply to all Virtex devices unless
otherwise noted.
IOB Input Switching Characteristics
Input delays associated with the pad are specified for LVTTL levels. For other standards, adjust the delays with the values
shown in , page 6.
Speed Grade
Description
Device
Symbol
Min
-6
-5
-4
Units
All
TIOPI
0.39
0.8
0.9
1.0
ns, max
XCV50
TIOPID
0.8
1.5
1.7
1.9
ns, max
XCV100
0.8
1.5
1.7
1.9
ns, max
XCV150
0.8
1.5
1.7
1.9
ns, max
XCV200
0.8
1.5
1.7
1.9
ns, max
XCV300
0.8
1.5
1.7
1.9
ns, max
XCV400
0.9
1.8
2.0
2.3
ns, max
XCV600
0.9
1.8
2.0
2.3
ns, max
XCV800
1.1
2.1
2.4
2.7
ns, max
XCV1000
1.1
2.1
2.4
2.7
ns, max
Propagation Delays
Pad to I output, no delay
Pad to I output, with delay
Pad to output IQ via transparent
latch, no delay
All
TIOPLI
0.8
1.6
1.8
2.0
ns, max
Pad to output IQ via transparent
latch, with delay
XCV50
TIOPLID
1.9
3.7
4.2
4.8
ns, max
XCV100
1.9
3.7
4.2
4.8
ns, max
XCV150
2.0
3.9
4.3
4.9
ns, max
XCV200
2.0
4.0
4.4
5.1
ns, max
XCV300
2.0
4.0
4.4
5.1
ns, max
XCV400
2.1
4.1
4.6
5.3
ns, max
XCV600
2.1
4.2
4.7
5.4
ns, max
XCV800
2.2
4.4
4.9
5.6
ns, max
XCV1000
2.3
4.5
5.1
5.8
ns, max
Sequential Delays
Clock CLK
All
Minimum Pulse Width, High
TCH
0.8
1.5
1.7
2.0
ns, min
Minimum Pulse Width, Low
TCL
0.8
1.5
1.7
2.0
ns, min
TIOCKIQ
0.2
0.7
0.7
0.8
ns, max
Clock CLK to output IQ
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Speed Grade
Description
Device
Symbol
Min
Setup and Hold Times with respect to Clock CLK at IOB input
register (1)
Pad, no delay
Pad, with delay
ICE input
-6
-5
-4
Units
Setup Time / Hold Time
All
TIOPICK/TIOICKP
0.8 / 0
1.6 / 0
1.8 / 0
2.0 / 0
ns, min
XCV50
TIOPICKD/TIOICKPD
1.9 / 0
3.7 / 0
4.1 / 0
4.7 / 0
ns, min
XCV100
1.9 / 0
3.7 / 0
4.1 / 0
4.7 / 0
ns, min
XCV150
1.9 / 0
3.8 / 0
4.3 / 0
4.9 / 0
ns, min
XCV200
2.0 / 0
3.9 / 0
4.4 / 0
5.0 / 0
ns, min
XCV300
2.0 / 0
3.9 / 0
4.4 / 0
5.0 / 0
ns, min
XCV400
2.1 / 0
4.1 / 0
4.6 / 0
5.3 / 0
ns, min
XCV600
2.1 / 0
4.2 / 0
4.7 / 0
5.4 / 0
ns, min
XCV800
2.2 / 0
4.4 / 0
4.9 / 0
5.6 / 0
ns, min
XCV1000
2.3 / 0
4.5 / 0
5.0 / 0
5.8 / 0
ns, min
All
TIOICECK/TIOCKICE
0.37/ 0
0.8 / 0
0.9 / 0
1.0 / 0
ns, max
SR input (IFF, synchronous)
All
TIOSRCKI
0.49
1.0
1.1
1.3
ns, max
SR input to IQ (asynchronous)
All
TIOSRIQ
0.70
1.4
1.6
1.8
ns, max
GSR to output IQ
All
TGSRQ
4.9
9.7
10.9
12.5
ns, max
Set/Reset Delays
Notes:
1. A Zero "0" Hold Time listing indicates no hold time or a negative hold time. Negative values cannot be guaranteed "best-case", but
if a "0" is listed, there is no positive hold time.
2. Input timing for LVTTL is measured at 1.4 V. For other I/O standards, see Table 3.
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Virtex™ 2.5 V Field Programmable Gate Arrays
IOB Input Switching Characteristics Standard Adjustments
Speed Grade
Description
Symbol
Standard (1)
Min
-6
-5
-4
Units
TILVTTL
LVTTL
0
0
0
0
ns
TILVCMOS2
LVCMOS2
–0.02
–0.04
–0.04
–0.05
ns
TIPCI33_3
PCI, 33 MHz, 3.3 V
–0.05
–0.11
–0.12
–0.14
ns
TIPCI33_5
PCI, 33 MHz, 5.0 V
0.13
0.25
0.28
0.33
ns
TIPCI66_3
PCI, 66 MHz, 3.3 V
–0.05
–0.11
–0.12
–0.14
ns
TIGTL
GTL
0.10
0.20
0.23
0.26
ns
TIGTLP
GTL+
0.06
0.11
0.12
0.14
ns
TIHSTL
HSTL
0.02
0.03
0.03
0.04
ns
TISSTL2
SSTL2
–0.04
–0.08
–0.09
–0.10
ns
TISSTL3
SSTL3
–0.02
–0.04
–0.05
–0.06
ns
TICTT
CTT
0.01
0.02
0.02
0.02
ns
TIAGP
AGP
–0.03
–0.06
–0.07
–0.08
ns
Data Input Delay Adjustments
Standard-specific data input delay
adjustments
Notes:
1. Input timing for LVTTL is measured at 1.4 V. For other I/O standards, see Table 3.
IOB Output Switching Characteristics
Output delays terminating at a pad are specified for LVTTL with 12 mA drive and fast slew rate. For other standards, adjust
the delays with the values shown in IOB Output Switching Characteristics Standard Adjustments, page 9.
Speed Grade
Description
Symbol
Min
-6
-5
-4
Units
O input to Pad
TIOOP
1.2
2.9
3.2
3.5
ns, max
O input to Pad via transparent latch
TIOOLP
1.4
3.4
3.7
4.0
ns, max
T input to Pad high-impedance (1)
TIOTHZ
1.0
2.0
2.2
2.4
ns, max
T input to valid data on Pad
TIOTON
1.4
3.1
3.3
3.7
ns, max
T input to Pad high-impedance via
transparent latch (1)
TIOTLPHZ
1.2
2.4
2.6
3.0
ns, max
T input to valid data on Pad via
transparent latch
TIOTLPON
1.6
3.5
3.8
4.2
ns, max
GTS to Pad high impedance (1)
TGTS
2.5
4.9
5.5
6.3
ns, max
Minimum Pulse Width, High
TCH
0.8
1.5
1.7
2.0
ns, min
Minimum Pulse Width, Low
TCL
0.8
1.5
1.7
2.0
ns, min
Propagation Delays
3-State Delays
Sequential Delays
Clock CLK
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Speed Grade
Description
Symbol
Min
-6
-5
-4
Units
Clock CLK to Pad delay with OBUFT
enabled (non-3-state)
TIOCKP
1.0
2.9
3.2
3.5
ns, max
Clock CLK to Pad high-impedance
(synchronous) (1)
TIOCKHZ
1.1
2.3
2.5
2.9
ns, max
Clock CLK to valid data on Pad delay, plus
enable delay for OBUFT
TIOCKON
1.5
3.4
3.7
4.1
ns, max
Setup and Hold Times before/after Clock CLK (2)
O input
Setup Time / Hold Time
TIOOCK/TIOCKO
0.51 / 0
1.1 / 0
1.2 / 0
1.3 / 0
ns, min
OCE input
TIOOCECK/TIOCKOCE
0.37 / 0
0.8 / 0
0.9 / 0
1.0 / 0
ns, min
SR input (OFF)
TIOSRCKO/TIOCKOSR
0.52 / 0
1.1 / 0
1.2 / 0
1.4 / 0
ns, min
TIOTCK/TIOCKT
0.34 / 0
0.7 / 0
0.8 / 0
0.9 / 0
ns, min
3-State Setup Times, TCE input
TIOTCECK/TIOCKTCE
0.41 / 0
0.9 / 0
0.9 / 0
1.1 / 0
ns, min
3-State Setup Times, SR input (TFF)
TIOSRCKT/TIOCKTSR
0.49 / 0
1.0 / 0
1.1 / 0
1.3 / 0
ns, min
SR input to Pad (asynchronous)
TIOSRP
1.6
3.8
4.1
4.6
ns, max
SR input to Pad high-impedance
(asynchronous) (1)
TIOSRHZ
1.6
3.1
3.4
3.9
ns, max
SR input to valid data on Pad
(asynchronous)
TIOSRON
2.0
4.2
4.6
5.1
ns, max
GSR to Pad
TIOGSRQ
4.9
9.7
10.9
12.5
ns, max
3-State Setup Times, T input
Set/Reset Delays
Notes:
1. 3-state turn-off delays should not be adjusted.
2. A Zero "0" Hold Time listing indicates no hold time or a negative hold time. Negative values can not be guaranteed "best-case", but
if a "0" is listed, there is no positive hold time.
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Virtex™ 2.5 V Field Programmable Gate Arrays
IOB Output Switching Characteristics Standard Adjustments
Output delays terminating at a pad are specified for LVTTL with 12 mA drive and fast slew rate. For other standards, adjust
the delays by the values shown.
Speed Grade
Description
Symbol
Standard (1)
Min
-6
-5
-4
Unit
s
TOLVTTL_S2
LVTTL, Slow, 2 mA
4.2
14.7
15.8
17.0
ns
TOLVTTL_S4
4 mA
2.5
7.5
8.0
8.6
ns
TOLVTTL_S6
6 mA
1.8
4.8
5.1
5.6
ns
TOLVTTL_S8
8 mA
1.2
3.0
3.3
3.5
ns
TOLVTTL_S12
12 mA
1.0
1.9
2.1
2.2
ns
TOLVTTL_S16
16 mA
0.9
1.7
1.9
2.0
ns
TOLVTTL_S24
24 mA
0.8
1.3
1.4
1.6
ns
TOLVTTL_F2
LVTTL, Fast, 2mA
1.9
13.1
14.0
15.1
ns
TOLVTTL_F4
4 mA
0.7
5.3
5.7
6.1
ns
TOLVTTL_F6
6 mA
0.2
3.1
3.3
3.6
ns
TOLVTTL_F8
8 mA
0.1
1.0
1.1
1.2
ns
TOLVTTL_F12
12 mA
0
0
0
0
ns
TOLVTTL_F16
16 mA
–0.10
–0.05
–0.05
–0.05
ns
TOLVTTL_F24
24 mA
–0.10
–0.20
–0.21
–0.23
ns
TOLVCMOS2
LVCMOS2
0.10
0.10
0.11
0.12
ns
TOPCI33_3
PCI, 33 MHz, 3.3 V
0.50
2.3
2.5
2.7
ns
TOPCI33_5
PCI, 33 MHz, 5.0 V
0.40
2.8
3.0
3.3
ns
TOPCI66_3
PCI, 66 MHz, 3.3 V
0.10
–0.40
–0.42
–0.46
ns
TOGTL
GTL
0.6
0.50
0.54
0.6
ns
TOGTLP
GTL+
0.7
0.8
0.9
1.0
ns
TOHSTL_I
HSTL I
0.10
–0.50
–0.53
–0.5
ns
TOHSTL_III
HSTL III
–0.10
–0.9
–0.9
–1.0
ns
TOHSTL_IV
HSTL IV
–0.20
–1.0
–1.0
–1.1
ns
TOSSTL2_I
SSTL2 I
–0.10
–0.50
–0.53
–0.5
ns
TOSSLT2_II
SSTL2 II
–0.20
–0.9
–0.9
–1.0
ns
TOSSTL3_I
SSTL3 I
–0.20
–0.50
–0.53
–0.5
ns
TOSSTL3_II
SSTL3 II
–0.30
–1.0
–1.0
–1.1
ns
TOCTT
CTT
0
–0.6
–0.6
–0.6
ns
TOAGP
AGP
0
–0.9
–0.9
–1.0
ns
Output Delay Adjustments
Standard-specific adjustments for
output delays terminating at pads
(based on standard capacitive load,
Csl)
Notes:
1. Output timing is measured at 1.4 V with 35 pF external capacitive load for LVTTL. For other I/O standards and different loads, see
Table 2 and Table 3.
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Calculation of Tioop as a Function of
Capacitance
For other capacitive loads, use the formulas below to calculate the corresponding Tioop.
Tioop is the propagation delay from the O Input of the IOB to
the pad. The values for Tioop were based on the standard
capacitive load (Csl) for each I/O standard as listed in
Table 2.
LVTTL Fast Slew Rate, 2mA drive
Where:
Topadjust is reported above in the Output Delay
Adjustment section.
Cload is the capacitive load for the design.
Table 2: Constants for Calculating Tioop
Standard
Tioop = Tioop + Topadjust + (Cload – Csl) * fl
Csl
(pF)
fl
(ns/pF)
35
0.41
Table 3: Delay Measurement Methodology
Standard
VL (1)
VH (1)
Meas.
Point
VREF
Typ (2)
LVTTL Fast Slew Rate, 4mA drive
35
0.20
LVTTL Fast Slew Rate, 6mA drive
35
0.13
LVTTL
0
3
1.4
-
LVTTL Fast Slew Rate, 8mA drive
35
0.079
LVCMOS2
0
2.5
1.125
-
LVTTL Fast Slew Rate, 12mA drive
35
0.044
PCI33_5
Per PCI Spec
-
LVTTL Fast Slew Rate, 16mA drive
35
0.043
PCI33_3
Per PCI Spec
-
LVTTL Fast Slew Rate, 24mA drive
35
0.033
PCI66_3
Per PCI Spec
-
LVTTL Slow Slew Rate, 2mA drive
35
0.41
LVTTL Slow Slew Rate, 4mA drive
35
0.20
LVTTL Slow Slew Rate, 6mA drive
35
0.100
LVTTL Slow Slew Rate, 8mA drive
35
LVTTL Slow Slew Rate, 12mA drive
GTL
VREF –0.2
VREF +0.2
VREF
0.80
GTL+
VREF –0.2
VREF +0.2
VREF
1.0
0.086
HSTL Class I
VREF –0.5
VREF +0.5
VREF
0.75
35
0.058
HSTL Class III
VREF –0.5
VREF +0.5
VREF
0.90
LVTTL Slow Slew Rate, 16mA drive
35
0.050
HSTL Class IV
VREF –0.5
VREF +0.5
VREF
0.90
LVTTL Slow Slew Rate, 24mA drive
35
0.048
SSTL3 I & II
VREF –1.0
VREF +1.0
VREF
1.5
LVCMOS2
35
0.041
SSTL2 I & II
VREF –0.75
VREF +0.75
VREF
1.25
PCI 33MHz 5V
50
0.050
CTT
10
0.050
VREF –0.2
VREF +0.2
VREF
1.5
PCI 33MHZ 3.3 V
PCI 66 MHz 3.3 V
10
0.033
VREF –
VREF +
VREF
GTL
0
0.014
(0.2xVCCO)
(0.2xVCCO)
Per
AGP
Spec
GTL+
0
0.017
HSTL Class I
20
0.022
HSTL Class III
20
0.016
HSTL Class IV
20
0.014
SSTL2 Class I
30
0.028
SSTL2 Class II
30
0.016
SSTL3 Class I
30
0.029
SSTL3 Class II
30
0.016
CTT
20
0.035
AGP
10
0.037
AGP
Notes:
1. Input waveform switches between VLand VH.
2. Measurements are made at VREF (Typ), Maximum, and
Minimum. Worst-case values are reported.
3. I/O parameter measurements are made with the capacitance
values shown in Table 2. See Application Note XAPP133 on
www.xilinx.com for appropriate terminations.
4. I/O standard measurements are reflected in the IBIS model
information except where the IBIS format precludes it.
Notes:
1. I/O parameter measurements are made with the capacitance
values shown above. See Application Note XAPP133 on
www.xilinx.com for appropriate terminations.
2. I/O standard measurements are reflected in the IBIS model
information except where the IBIS format precludes it.
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Clock Distribution Guidelines
Speed Grade
Description
Device
Symbol
-6
-5
-4
Units
XCV50
TGSKEWIOB
0.10
0.12
0.14
ns, max
XCV100
0.12
0.13
0.15
ns, max
XCV150
0.12
0.13
0.15
ns, max
XCV200
0.13
0.14
0.16
ns, max
XCV300
0.14
0.16
0.18
ns, max
XCV400
0.13
0.13
0.14
ns, max
XCV600
0.14
0.15
0.17
ns, max
XCV800
0.16
0.17
0.20
ns, max
XCV1000
0.20
0.23
0.25
ns, max
Global Clock Skew (1)
Global Clock Skew between IOB Flip-flops
Notes:
1. These clock-skew delays are provided for guidance only. They reflect the delays encountered in a typical design under worst-case
conditions. Precise values for a particular design are provided by the timing analyzer.
Clock Distribution Switching Characteristics
Speed Grade
Description
Symbol
Min
-6
-5
-4
Units
Global Clock PAD to output.
TGPIO
0.33
0.7
0.8
0.9
ns, max
Global Clock Buffer I input to O output
TGIO
0.34
0.7
0.8
0.9
ns, max
GCLK IOB and Buffer
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I/O Standard Global Clock Input Adjustments
Speed Grade
Description
Symbol
Standard (1)
Min
-6
-5
-4
Units
TGPLVTTL
LVTTL
0
0
0
0
ns,
max
TGPLVCMOS
LVCMOS2
–0.02
–0.04
–0.04
–0.05
ns,
max
TGPPCI33_3
PCI, 33 MHz, 3.3
V
–0.05
–0.11
–0.12
–0.14
ns,
max
TGPPCI33_5
PCI, 33 MHz, 5.0
V
0.13
0.25
0.28
0.33
ns,
max
TGPPCI66_3
PCI, 66 MHz, 3.3
V
–0.05
–0.11
–0.12
–0.14
ns,
max
TGPGTL
GTL
0.7
0.8
0.9
0.9
ns,
max
TGPGTLP
GTL+
0.7
0.8
0.8
0.8
ns,
max
TGPHSTL
HSTL
0.7
0.7
0.7
0.7
ns,
max
TGPSSTL2
SSTL2
0.6
0.52
0.51
0.50
ns,
max
TGPSSTL3
SSTL3
0.6
0.6
0.55
0.54
ns,
max
TGPCTT
CTT
0.7
0.7
0.7
0.7
ns,
max
TGPAGP
AGP
0.6
0.54
0.53
0.52
ns,
max
Data Input Delay Adjustments
Standard-specific global clock input
delay adjustments
2
Notes:
1. Input timing for GPLVTTL is measured at 1.4 V. For other I/O standards, see Table 3.
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Virtex™ 2.5 V Field Programmable Gate Arrays
CLB Switching Characteristics
Delays originating at F/G inputs vary slightly according to the input used. The values listed below are worst-case. Precise
values are provided by the timing analyzer.
Speed Grade
Description
Symbol
Min
-6
-5
-4
Units
4-input function: F/G inputs to X/Y outputs
TILO
0.29
0.6
0.7
0.8
ns, max
5-input function: F/G inputs to F5 output
TIF5
0.32
0.7
0.8
0.9
ns, max
5-input function: F/G inputs to X output
TIF5X
0.36
0.8
0.8
1.0
ns, max
6-input function: F/G inputs to Y output via F6 MUX
TIF6Y
0.44
0.9
1.0
1.2
ns, max
6-input function: F5IN input to Y output
TF5INY
0.17
0.32
0.36
0.42
ns, max
Incremental delay routing through transparent latch
to XQ/YQ outputs
TIFNCTL
0.31
0.7
0.7
0.8
ns, max
TBYYB
0.27
0.53
0.6
0.7
ns, max
FF Clock CLK to XQ/YQ outputs
TCKO
0.54
1.1
1.2
1.4
ns, max
Latch Clock CLK to XQ/YQ outputs
TCKLO
0.6
1.2
1.4
1.6
ns, max
Combinatorial Delays
BY input to YB output
Sequential Delays
Setup and Hold Times before/after Clock CLK (1)
Setup Time / Hold Time
4-input function: F/G Inputs
TICK/TCKI
0.6 / 0
1.2 / 0
1.4 / 0
1.5 / 0
ns, min
5-input function: F/G inputs
TIF5CK/TCKIF5
0.7 / 0
1.3 / 0
1.5 / 0
1.7 / 0
ns, min
6-input function: F5IN input
TF5INCK/TCKF5IN
0.46 / 0
1.0 / 0
1.1 / 0
1.2 / 0
ns, min
TIF6CK/TCKIF6
0.8 / 0
1.5 / 0
1.7 / 0
1.9 / 0
ns, min
TDICK/TCKDI
0.30 / 0
0.6 / 0
0.7 / 0
0.8 / 0
ns, min
TCECK/TCKCE
0.37 / 0
0.8 / 0
0.9 / 0
1.0 / 0
ns, min
TRCKTCKR
0.33 / 0
0.7 / 0
0.8 / 0
0.9 / 0
ns, min
Minimum Pulse Width, High
TCH
0.8
1.5
1.7
2.0
ns, min
Minimum Pulse Width, Low
TCL
0.8
1.5
1.7
2.0
ns, min
TRPW
1.3
2.5
2.8
3.3
ns, min
TRQ
0.54
1.1
1.3
1.4
ns, max
TIOGSRQ
4.9
9.7
10.9
12.5
ns, max
FTOG (MHz)
625
333
294
250
MHz
6-input function: F/G inputs via F6 MUX
BX/BY inputs
CE input
SR/BY inputs (synchronous)
Clock CLK
Set/Reset
Minimum Pulse Width, SR/BY inputs
Delay from SR/BY inputs to XQ/YQ outputs
(asynchronous)
Delay from GSR to XQ/YQ outputs
Toggle Frequency (MHz) (for export control)
Notes:
1. A Zero "0" Hold Time listing indicates no hold time or a negative hold time. Negative values cannot be guaranteed "best-case", but
if a "0" is listed, there is no positive hold time.
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Virtex™ 2.5 V Field Programmable Gate Arrays
CLB Arithmetic Switching Characteristics
Setup times not listed explicitly can be approximated by decreasing the combinatorial delays by the setup time adjustment
listed. Precise values are provided by the timing analyzer.
Speed Grade
Description
Symbol
Min
-6
-5
-4
Units
F operand inputs to X via XOR
TOPX
0.37
0.8
0.9
1.0
ns, max
F operand input to XB output
TOPXB
0.54
1.1
1.3
1.4
ns, max
F operand input to Y via XOR
TOPY
0.8
1.5
1.7
2.0
ns, max
F operand input to YB output
TOPYB
0.8
1.5
1.7
2.0
ns, max
F operand input to COUT output
TOPCYF
0.6
1.2
1.3
1.5
ns, max
G operand inputs to Y via XOR
TOPGY
0.46
1.0
1.1
1.2
ns, max
G operand input to YB output
TOPGYB
0.8
1.6
1.8
2.1
ns, max
G operand input to COUT output
TOPCYG
0.7
1.3
1.4
1.6
ns, max
BX initialization input to COUT
TBXCY
0.41
0.9
1.0
1.1
ns, max
CIN input to X output via XOR
TCINX
0.21
0.41
0.46
0.53
ns, max
CIN input to XB
TCINXB
0.02
0.04
0.05
0.06
ns, max
CIN input to Y via XOR
TCINY
0.23
0.46
0.52
0.6
ns, max
CIN input to YB
TCINYB
0.23
0.45
0.51
0.6
ns, max
TBYP
0.05
0.09
0.10
0.11
ns, max
F1/2 operand inputs to XB output via AND
TFANDXB
0.18
0.36
0.40
0.46
ns, max
F1/2 operand inputs to YB output via AND
TFANDYB
0.40
0.8
0.9
1.1
ns, max
F1/2 operand inputs to COUT output via AND
TFANDCY
0.22
0.43
0.48
0.6
ns, max
G1/2 operand inputs to YB output via AND
TGANDYB
0.25
0.50
0.6
0.7
ns, max
G1/2 operand inputs to COUT output via AND
TGANDCY
0.07
0.13
0.15
0.17
ns, max
Combinatorial Delays
CIN input to COUT output
Multiplier Operation
Setup and Hold Times before/after Clock
CLK (1)
Setup Time / Hold Time
CIN input to FFX
TCCKX/TCKCX
0.50 / 0
1.0 / 0
1.2 / 0
1.3 / 0
ns, min
CIN input to FFY
TCCKY/TCKCY
0.53 / 0
1.1 / 0
1.2 / 0
1.4 / 0
ns, min
Notes:
1. A Zero "0" Hold Time listing indicates no hold time or a negative hold time. Negative values can not be guaranteed "best-case", but
if a "0" is listed, there is no positive hold time.
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Virtex™ 2.5 V Field Programmable Gate Arrays
CLB SelectRAM Switching Characteristics
Speed Grade
Description
Symbol
Min
-6
-5
-4
Units
Clock CLK to X/Y outputs (WE active) 16 x 1 mode
TSHCKO16
1.2
2.3
2.6
3.0
ns, max
Clock CLK to X/Y outputs (WE active) 32 x 1 mode
TSHCKO32
1.2
2.7
3.1
3.5
ns, max
TREG
1.2
3.7
4.1
4.7
ns, max
Sequential Delays
Shift-Register Mode
Clock CLK to X/Y outputs
Setup and Hold Times before/after Clock CLK (1)
Setup Time / Hold Time
F/G address inputs
TAS/TAH
0.25 / 0
0.5 / 0
0.6 / 0
0.7 / 0
ns, min
BX/BY data inputs (DIN)
TDS/TDH
0.34 / 0
0.7 / 0
0.8 / 0
0.9 / 0
ns, min
CE input (WE)
TWS/TWH
0.38 / 0
0.8 / 0
0.9 / 0
1.0 / 0
ns, min
BX/BY data inputs (DIN)
TSHDICK
0.34
0.7
0.8
0.9
ns, min
CE input (WS)
TSHCECK
0.38
0.8
0.9
1.0
ns, min
Minimum Pulse Width, High
TWPH
1.2
2.4
2.7
3.1
ns, min
Minimum Pulse Width, Low
TWPL
1.2
2.4
2.7
3.1
ns, min
Minimum clock period to meet address write cycle
time
TWC
2.4
4.8
5.4
6.2
ns, min
Minimum Pulse Width, High
TSRPH
1.2
2.4
2.7
3.1
ns, min
Minimum Pulse Width, Low
TSRPL
1.2
2.4
2.7
3.1
ns, min
Shift-Register Mode
Clock CLK
Shift-Register Mode
Notes:
1. A Zero "0" Hold Time listing indicates no hold time or a negative hold time. Negative values can not be guaranteed "best-case", but
if a "0" is listed, there is no positive hold time.
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Block RAM Switching Characteristics
Speed Grade
Description
Symbol
Min
-6
-5
-4
Units
TBCKO
1.7
3.4
3.8
4.3
ns, max
Sequential Delays
Clock CLK to DOUT output
Setup and Hold Times before/after Clock CLK (1)
Setup Time / Hold Time
ADDR inputs
TBACK/TBCKA
0.6 / 0
1.2 / 0
1.3 / 0
1.5 / 0
ns, min
DIN inputs
TBDCK/TBCKD
0.6 / 0
1.2 / 0
1.3 / 0
1.5 / 0
ns, min
EN input
TBECK/TBCKE
1.3 / 0
2.6 / 0
3.0 / 0
3.4 / 0
ns, min
RST input
TBRCK/TBCKR
1.3 / 0
2.5 / 0
2.7 / 0
3.2 / 0
ns, min
WEN input
TBWCK/TBCKW
1.2 / 0
2.3 / 0
2.6 / 0
3.0 / 0
ns, min
Minimum Pulse Width, High
TBPWH
0.8
1.5
1.7
2.0
ns, min
Minimum Pulse Width, Low
TBPWL
0.8
1.5
1.7
2.0
ns, min
CLKA -> CLKB setup time for different ports
TBCCS
3.0
3.5
4.0
ns, min
Clock CLK
Notes:
1. A Zero "0" Hold Time listing indicates no hold time or a negative hold time. Negative values can not be guaranteed "best-case", but
if a "0" is listed, there is no positive hold time.
TBUF Switching Characteristics
Speed Grade
Description
Symbol
Min
-6
-5
-4
Units
TIO
0
0
0
0
ns, max
TRI input to OUT output high-impedance
TOFF
0.05
0.09
0.10
0.11
ns, max
TRI input to valid data on OUT output
TON
0.05
0.09
0.10
0.11
ns, max
Combinatorial Delays
IN input to OUT output
JTAG Test Access Port Switching Characteristics
Speed Grade
Description
Symbol
-6
-5
-4
Units
TMS and TDI Setup times before TCK
TTAPTCK
4.0
4.0
4.0
ns, min
TMS and TDI Hold times after TCK
TTCKTAP
2.0
2.0
2.0
ns, min
Output delay from clock TCK to output TDO
TTCKTDO
11.0
11.0
11.0
ns, max
FTCK
33
33
33
MHz, max
Maximum TCK clock frequency
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Virtex™ 2.5 V Field Programmable Gate Arrays
Virtex Pin-to-Pin Output Parameter Guidelines
All devices are 100% functionally tested. Listed below are representative values for typical pin locations and normal clock
loading. Values are expressed in nanoseconds unless otherwise noted.
Global Clock Input to Output Delay for LVTTL, 12 mA, Fast Slew Rate, with DLL
Speed Grade
Description
Symbol
Device
Min
-6
-5
-4
Units
LVTTL Global Clock Input to Output Delay using
Output Flip-flop, 12 mA, Fast Slew Rate, with DLL.
For data output with different standards, adjust
delays with the values shown in Output Delay
Adjustments.
TICKOFDLL
XCV50
1.0
3.1
3.3
3.6
ns, max
XCV100
1.0
3.1
3.3
3.6
ns, max
XCV150
1.0
3.1
3.3
3.6
ns, max
XCV200
1.0
3.1
3.3
3.6
ns, max
XCV300
1.0
3.1
3.3
3.6
ns, max
XCV400
1.0
3.1
3.3
3.6
ns, max
XCV600
1.0
3.1
3.3
3.6
ns, max
XCV800
1.0
3.1
3.3
3.6
ns, max
XCV1000
1.0
3.1
3.3
3.6
ns, max
Notes:
1. Listed above are representative values where one global clock input drives one vertical clock line in each accessible column, and
where all accessible IOB and CLB flip-flops are clocked by the global clock net.
2. Output timing is measured at 1.4 V with 35 pF external capacitive load for LVTTL. The 35 pF load does not apply to the Min values.
For other I/O standards and different loads, see Table 2 and Table 3.
3. DLL output jitter is already included in the timing calculation.
Global Clock Input-to-Output Delay for LVTTL, 12 mA, Fast Slew Rate, without DLL
Speed Grade
Description
Symbol
Device
Min
-6
-5
-4
Units
LVTTL Global Clock Input to Output Delay using
Output Flip-flop, 12 mA, Fast Slew Rate, without DLL.
For data output with different standards, adjust
delays with the values shown in Input and Output
Delay Adjustments.
For I/O standards requiring VREF, such as GTL,
GTL+, SSTL, HSTL, CTT, and AGO, an additional
600 ps must be added.
TICKOF
XCV50
1.5
4.6
5.1
5.7
ns, max
XCV100
1.5
4.6
5.1
5.7
ns, max
XCV150
1.5
4.7
5.2
5.8
ns, max
XCV200
1.5
4.7
5.2
5.8
ns, max
XCV300
1.5
4.7
5.2
5.9
ns, max
XCV400
1.5
4.8
5.3
6.0
ns, max
XCV600
1.6
4.9
5.4
6.0
ns, max
XCV800
1.6
4.9
5.5
6.2
ns, max
XCV1000
1.7
5.0
5.6
6.3
ns, max
Notes:
1. Listed above are representative values where one global clock input drives one vertical clock line in each accessible column, and
where all accessible IOB and CLB flip-flops are clocked by the global clock net.
2. Output timing is measured at 1.4 V with 35 pF external capacitive load for LVTTL. The 35 pF load does not apply to the Min values.
For other I/O standards and different loads, see Table 2 and Table 3.
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Minimum Clock-to-Out for Virtex Devices
With DLL
I/O Standard
Without DLL
All Devices
V50
V100
V150
V200
V300
V400
V600
V800
V1000
Units
*LVTTL_S2
5.2
6.0
6.0
6.0
6.0
6.1
6.1
6.1
6.1
6.1
ns
*LVTTL_S4
3.5
4.3
4.3
4.3
4.3
4.4
4.4
4.4
4.4
4.4
ns
*LVTTL_S6
2.8
3.6
3.6
3.6
3.6
3.7
3.7
3.7
3.7
3.7
ns
*LVTTL_S8
2.2
3.1
3.1
3.1
3.1
3.1
3.1
3.2
3.2
3.2
ns
*LVTTL_S12
2.0
2.9
2.9
2.9
2.9
2.9
2.9
3.0
3.0
3.0
ns
*LVTTL_S16
1.9
2.8
2.8
2.8
2.8
2.8
2.8
2.9
2.9
2.9
ns
*LVTTL_S24
1.8
2.6
2.6
2.7
2.7
2.7
2.7
2.7
2.7
2.8
ns
*LVTTL_F2
2.9
3.8
3.8
3.8
3.8
3.8
3.8
3.9
3.9
3.9
ns
*LVTTL_F4
1.7
2.6
2.6
2.6
2.6
2.6
2.6
2.7
2.7
2.7
ns
*LVTTL_F6
1.2
2.0
2.0
2.0
2.1
2.1
2.1
2.1
2.1
2.2
ns
*LVTTL_F8
1.1
1.9
1.9
1.9
1.9
2.0
2.0
2.0
2.0
2.0
ns
*LVTTL_F12
1.0
1.8
1.8
1.8
1.8
1.9
1.9
1.9
1.9
1.9
ns
*LVTTL_F16
0.9
1.7
1.8
1.8
1.8
1.8
1.8
1.8
1.9
1.9
ns
*LVTTL_F24
0.9
1.7
1.7
1.7
1.8
1.8
1.8
1.8
1.8
1.9
ns
LVCMOS2
1.1
1.9
1.9
1.9
2.0
2.0
2.0
2.0
2.0
2.1
ns
PCI33_3
1.5
2.4
2.4
2.4
2.4
2.4
2.4
2.5
2.5
2.5
ns
PCI33_5
1.4
2.2
2.2
2.3
2.3
2.3
2.3
2.3
2.3
2.4
ns
PCI66_3
1.1
1.9
1.9
2.0
2.0
2.0
2.0
2.0
2.1
2.1
ns
GTL
1.6
2.5
2.5
2.5
2.5
2.5
2.5
2.6
2.6
2.6
ns
GTL+
1.7
2.5
2.5
2.6
2.6
2.6
2.6
2.6
2.6
2.7
ns
HSTL I
1.1
1.9
1.9
1.9
1.9
2.0
2.0
2.0
2.0
2.0
ns
HSTL III
0.9
1.7
1.7
1.8
1.8
1.8
1.8
1.8
1.8
1.9
ns
HSTL IV
0.8
1.6
1.6
1.6
1.7
1.7
1.7
1.7
1.7
1.8
ns
SSTL2 I
0.9
1.7
1.7
1.7
1.7
1.8
1.8
1.8
1.8
1.8
ns
SSTL2 II
0.8
1.6
1.6
1.6
1.6
1.7
1.7
1.7
1.7
1.7
ns
SSTL3 I
0.8
1.6
1.7
1.7
1.7
1.7
1.7
1.7
1.8
1.8
ns
SSTL3 II
0.7
1.5
1.5
1.6
1.6
1.6
1.6
1.6
1.6
1.7
ns
CTT
1.0
1.8
1.8
1.8
1.9
1.9
1.9
1.9
1.9
2.0
ns
AGP
1.0
1.8
1.8
1.9
1.9
1.9
1.9
1.9
1.9
2.0
ns
*S = Slow Slew Rate, F = Fast Slew Rate
Notes:
1. Listed above are representative values where one global clock input drives one vertical clock line in each accessible column, and
where all accessible IOB and CLB flip-flops are clocked by the global clock net.
2. Input and output timing is measured at 1.4 V for LVTTL. For other I/O standards, see Table 3. In all cases, an 8 pF external capacitive
load is used.
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Virtex Pin-to-Pin Input Parameter Guidelines
All devices are 100% functionally tested. Listed below are representative values for typical pin locations and normal clock
loading. Values are expressed in nanoseconds unless otherwise noted
Global Clock Set-Up and Hold for LVTTL Standard, with DLL
Speed Grade
Description
Symbol
Device
Min
-6
-5
-4
Units
Input Setup and Hold Time Relative to Global Clock Input Signal for LVTTL Standard. For data input with different
standards, adjust the setup time delay by the values shown in Input Delay Adjustments.
No Delay
TPSDLL/TPHDLL
XCV50
0.40 / –0.4
1.7 /–0.4
1.8 /–0.4
2.1 /–0.4
ns,
min
XCV100
0.40 /–0.4
1.7 /–0.4
1.9 /–0.4
2.1 /–0.4
ns,
min
XCV150
0.40 /–0.4
1.7 /–0.4
1.9 /–0.4
2.1 /–0.4
ns,
min
XCV200
0.40 /–0.4
1.7 /–0.4
1.9 /–0.4
2.1 /–0.4
ns,
min
XCV300
0.40 /–0.4
1.7 /–0.4
1.9 /–0.4
2.1 /–0.4
ns,
min
XCV400
0.40 /–0.4
1.7 /–0.4
1.9 /–0.4
2.1 /–0.4
ns,
min
XCV600
0.40 /–0.4
1.7 /–0.4
1.9 /–0.4
2.1 /–0.4
ns,
min
XCV800
0.40 /–0.4
1.7 /–0.4
1.9 /–0.4
2.1 /–0.4
ns,
min
XCV1000
0.40 /–0.4
1.7 /–0.4
1.9 /–0.4
2.1 /–0.4
ns,
min
Global Clock and IFF, with DLL
IFF = Input Flip-Flop or Latch
Notes:
1. Set-up time is measured relative to the Global Clock input signal with the fastest route and the lightest load. Hold time is measured
relative to the Global Clock input signal with the slowest route and heaviest load.
2. DLL output jitter is already included in the timing calculation.
3. A Zero "0" Hold Time listing indicates no hold time or a negative hold time. Negative values can not be guaranteed "best-case", but
if a "0" is listed, there is no positive hold time.
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Global Clock Set-Up and Hold for LVTTL Standard, without DLL
Speed Grade
Description
Symbol
Device
Min
-6
-5
-4
Units
Input Setup and Hold Time Relative to Global Clock Input Signal for LVTTL Standard. (2) For data input with different
standards, adjust the setup time delay by the values shown in Input Delay Adjustments.
Full Delay
Global Clock and IFF, without
DLL
TPSFD/TPHFD
XCV50
0.6 / 0
2.3 / 0
2.6 / 0
2.9 / 0
ns,
min
XCV100
0.6 / 0
2.3 / 0
2.6 / 0
3.0 / 0
ns,
min
XCV150
0.6 / 0
2.4 / 0
2.7 / 0
3.1 / 0
ns,
min
XCV200
0.7 / 0
2.5 / 0
2.8 / 0
3.2 / 0
ns,
min
XCV300
0.7 / 0
2.5 / 0
2.8 / 0
3.2 / 0
ns,
min
XCV400
0.7 / 0
2.6 / 0
2.9 / 0
3.3 / 0
ns,
min
XCV600
0.7 / 0
2.6 / 0
2.9 / 0
3.3 / 0
ns,
min
XCV800
0.7 / 0
2.7 / 0
3.1 / 0
3.5 / 0
ns,
min
XCV1000
0.7 / 0
2.8 / 0
3.1 / 0
3.6 / 0
ns,
min
IFF = Input Flip-Flop or Latch
Notes: Notes:
1. Set-up time is measured relative to the Global Clock input signal with the fastest route and the lightest load. Hold time is measured
relative to the Global Clock input signal with the slowest route and heaviest load.
2. A Zero "0" Hold Time listing indicates no hold time or a negative hold time. Negative values can not be guaranteed "best-case", but
if a "0" is listed, there is no positive hold time.
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DLL Timing Parameters
All devices are 100 percent functionally tested. Because of the difficulty in directly measuring many internal timing
parameters, those parameters are derived from benchmark timing patterns. The following guidelines reflect worst-case
values across the recommended operating conditions.
Speed Grade
-6
Description
-5
-4
Symbol
Min
Max
Min
Max
Min
Max
Units
Input Clock Frequency (CLKDLLHF)
FCLKINHF
60
200
60
180
60
180
MHz
Input Clock Frequency (CLKDLL)
FCLKINLF
25
100
25
90
25
90
MHz
Input Clock Pulse Width (CLKDLLHF)
TDLLPWHF
2.0
-
2.4
-
2.4
-
ns
Input Clock Pulse Width (CLKDLL)
TDLLPWLF
2.5
-
3.0
3.0
-
ns
Notes:
1. All specifications correspond to Commercial Operating Temperatures (0°C to + 85°C).
DLL Clock Tolerance, Jitter, and Phase Information
All DLL output jitter and phase specifications determined through statistical measurement at the package pins using a clock
mirror configuration and matched drivers.
CLKDLLHF
Description
Symbol
FCLKIN
CLKDLL
Min
Max
Min
Max
Units
Input Clock Period Tolerance
TIPTOL
-
1.0
-
1.0
ns
Input Clock Jitter Tolerance (Cycle to Cycle)
TIJITCC
-
± 150
-
± 300
ps
Time Required for DLL to Acquire Lock
TLOCK
> 60 MHz
-
20
-
20
μs
50 - 60 MHz
-
-
-
25
μs
40 - 50 MHz
-
-
-
50
μs
30 - 40 MHz
-
-
-
90
μs
25 - 30 MHz
-
-
-
120
μs
TOJITCC
± 60
± 60
ps
TPHIO
± 100
± 100
ps
Phase Offset between Clock Outputs on the DLL (3)
TPHOO
± 140
± 140
ps
Maximum Phase Difference between CLKIN and
CLKO (4)
TPHIOM
± 160
± 160
ps
Maximum Phase Difference between Clock Outputs on
the DLL (5)
TPHOOM
± 200
± 200
ps
Output Jitter (cycle-to-cycle) for any DLL Clock Output (1)
Phase Offset between CLKIN and
CLKO (2)
Notes:
1. Output Jitter is cycle-to-cycle jitter measured on the DLL output clock, excluding input clock jitter.
2. Phase Offset between CLKIN and CLKO is the worst-case fixed time difference between rising edges of CLKIN and CLKO,
excluding Output Jitter and input clock jitter.
3. Phase Offset between Clock Outputs on the DLL is the worst-case fixed time difference between rising edges of any two DLL
outputs, excluding Output Jitter and input clock jitter.
4. Maximum Phase Difference between CLKIN an CLKO is the sum of Output Jitter and Phase Offset between CLKIN and CLKO,
or the greatest difference between CLKIN and CLKO rising edges due to DLL alone (excluding input clock jitter).
5. Maximum Phase DIfference between Clock Outputs on the DLL is the sum of Output JItter and Phase Offset between any DLL
clock outputs, or the greatest difference between any two DLL output rising edges sue to DLL alone (excluding input clock jitter).
6. All specifications correspond to Commercial Operating Temperatures (0°C to +85°C).
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Period Tolerance: the allowed input clock period change in nanoseconds.
TCLKIN +_ TIPTOL
TCLKIN
Output Jitter: the difference between an ideal
reference clock edge and the actual design.
Phase Offset and Maximum Phase Difference
Ideal Period
Actual Period
+ Jitter
+/- Jitter
+ Maximum
Phase Difference
+ Phase Offset
ds003_20c_110399
Figure 1: Frequency Tolerance and Clock Jitter
Revision History
Date
Version
11/98
1.0
Initial Xilinx release.
01/99
1.2
Updated package drawings and specs.
02/99
1.3
Update of package drawings, updated specifications.
05/99
1.4
Addition of package drawings and specifications.
05/99
1.5
Replaced FG 676 & FG680 package drawings.
07/99
1.6
Changed Boundary Scan Information and changed Figure 11, Boundary Scan Bit
Sequence. Updated IOB Input & Output delays. Added Capacitance info for different I/O
Standards. Added 5 V tolerant information. Added DLL Parameters and waveforms and
new Pin-to-pin Input and Output Parameter tables for Global Clock Input to Output and
Setup and Hold. Changed Configuration Information including Figures 12, 14, 17 & 19.
Added device-dependent listings for quiescent currents ICCINTQ and ICCOQ. Updated
IOB Input and Output Delays based on default standard of LVTTL, 12 mA, Fast Slew Rate.
Added IOB Input Switching Characteristics Standard Adjustments.
09/99
1.7
Speed grade update to preliminary status, Power-on specification and Clock-to-Out
Minimums additions, "0" hold time listing explanation, quiescent current listing update, and
Figure 6 ADDRA input label correction. Added TIJITCC parameter, changed TOJIT to TOPHASE.
01/00
1.8
Update to speed.txt file 1.96. Corrections for CRs 111036,111137, 112697, 115479,
117153, 117154, and 117612. Modified notes for Recommended Operating Conditions
(voltage and temperature). Changed Bank information for VCCO in CS144 package on p.43.
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Date
Version
Revision
01/00
1.9
Updated DLL Jitter Parameter table and waveforms, added Delay Measurement
Methodology table for different I/O standards, changed buffered Hex line info and
Input/Output Timing measurement notes.
03/00
2.0
New TBCKO values; corrected FG680 package connection drawing; new note about status
of CCLK pin after configuration.
05/00
2.1
Modified "Pins not listed..." statement. Speed grade update to Final status.
05/00
2.2
Modified Table 18.
09/00
2.3
•
•
•
Added XCV400 values to table under Minimum Clock-to-Out for Virtex Devices.
Corrected Units column in table under IOB Input Switching Characteristics.
Added values to table under CLB SelectRAM Switching Characteristics.
10/00
2.4
•
•
Corrected Pinout information for devices in the BG256, BG432, and BG560 packages in
Table 18.
Corrected BG256 Pin Function Diagram.
04/02/01
2.5
•
•
Revised minimums for Global Clock Set-Up and Hold for LVTTL Standard, with DLL.
Converted file to modularized format. See the Virtex Data Sheet section.
04/19/01
2.6
•
Clarified TIOCKP and TIOCKON IOB Output Switching Characteristics descriptors.
07/19/01
2.7
•
Under Absolute Maximum Ratings, changed (TSOL) to 220 °C.
07/26/01
2.8
•
Removed TSOL parameter and added footnote to Absolute Maximum Ratings table.
10/29/01
2.9
•
Updated the speed grade designations used in data sheets, and added Table 1, which
shows the current speed grade designation for each device.
02/01/02
3.0
•
Added footnote to DC Input and Output Levels table.
07/19/02
3.1
•
•
Removed mention of MIL-M-38510/605 specification.
Added link to xapp158 from the Power-On Power Supply Requirements section.
09/10/02
3.2
•
Added Clock CLK to IOB Input Switching Characteristics and IOB Output Switching
Characteristics.
03/01/13
4.0
The products listed in this data sheet are obsolete. See XCN10016 for further information.
Virtex Data Sheet
The Virtex Data Sheet contains the following modules:
•
DS003-1, Virtex 2.5V FPGAs:
Introduction and Ordering Information (Module 1)
•
DS003-3, Virtex 2.5V FPGAs:
DC and Switching Characteristics (Module 3)
•
DS003-2, Virtex 2.5V FPGAs:
Functional Description (Module 2)
•
DS003-4, Virtex 2.5V FPGAs:
Pinout Tables (Module 4)
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Virtex Pin Definitions
Table 1: Special Purpose Pins
Dedicated
Pin
Direction
Description
GCK0, GCK1,
GCK2, GCK3
Yes
Input
Clock input pins that connect to Global Clock Buffers. These pins become
user inputs when not needed for clocks.
M0, M1, M2
Yes
Input
Mode pins are used to specify the configuration mode.
CCLK
Yes
Input or
Output
PROGRAM
Yes
Input
DONE
Yes
Bidirectional
Indicates that configuration loading is complete, and that the start-up
sequence is in progress. The output can be open drain.
INIT
No
Bidirectional
(Open-drain)
When Low, indicates that the configuration memory is being cleared. The
pin becomes a user I/O after configuration.
BUSY/
No
Output
In SelectMAP mode, BUSY controls the rate at which configuration data
is loaded. The pin becomes a user I/O after configuration unless the
SelectMAP port is retained.
Pin Name
DOUT
The configuration Clock I/O pin: it is an input for SelectMAP and
slave-serial modes, and output in master-serial mode. After configuration,
it is input only, logic level = Don’t Care.
Initiates a configuration sequence when asserted Low.
In bit-serial modes, DOUT provides header information to downstream
devices in a daisy-chain. The pin becomes a user I/O after configuration.
D0/DIN,
D1, D2,
D3, D4,
D5, D6,
D7
No
Input or
Output
In SelectMAP mode, D0 - D7 are configuration data pins. These pins
become user I/Os after configuration unless the SelectMAP port is
retained.
WRITE
No
Input
In SelectMAP mode, the active-low Write Enable signal. The pin becomes
a user I/O after configuration unless the SelectMAP port is retained.
CS
No
Input
In SelectMAP mode, the active-low Chip Select signal. The pin becomes
a user I/O after configuration unless the SelectMAP port is retained.
TDI, TDO,
TMS, TCK
Yes
Mixed
Boundary-scan Test-Access-Port pins, as defined in IEEE 1149.1.
DXN, DXP
Yes
N/A
Temperature-sensing diode pins. (Anode: DXP, cathode: DXN)
VCCINT
Yes
Input
Power-supply pins for the internal core logic.
VCCO
Yes
Input
Power-supply pins for the output drivers (subject to banking rules)
VREF
No
Input
Input threshold voltage pins. Become user I/Os when an external
threshold voltage is not needed (subject to banking rules).
GND
Yes
Input
Ground
In bit-serial modes, DIN is the single data input. This pin becomes a user
I/O after configuration.
© 1999-2013 Xilinx, Inc. All rights reserved. All Xilinx trademarks, registered trademarks, patents, and disclaimers are as listed at http://www.xilinx.com/legal.htm.
All other trademarks and registered trademarks are the property of their respective owners. All specifications are subject to change without notice.
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Virtex Pinout Information
Pinout Tables
See www.xilinx.com for updates or additional pinout information. For convenience, Table 2, Table 3 and Table 4 list the
locations of special-purpose and power-supply pins. Pins not listed are either user I/Os or not connected, depending on the
device/package combination. See the Pinout Diagrams starting on page 17 for any pins not listed for a particular
part/package combination.
Table 2: Virtex Pinout Tables (Chip-Scale and QFP Packages)
Pin Name
Device
CS144
TQ144
PQ/HQ240
GCK0
All
K7
90
92
GCK1
All
M7
93
89
GCK2
All
A7
19
210
GCK3
All
A6
16
213
M0
All
M1
110
60
M1
All
L2
112
58
M2
All
N2
108
62
CCLK
All
B13
38
179
PROGRAM
All
L12
72
122
DONE
All
M12
74
120
INIT
All
L13
71
123
BUSY/DOUT
All
C11
39
178
D0/DIN
All
C12
40
177
D1
All
E10
45
167
D2
All
E12
47
163
D3
All
F11
51
156
D4
All
H12
59
145
D5
All
J13
63
138
D6
All
J11
65
134
D7
All
K10
70
124
WRITE
All
C10
32
185
CS
All
D10
33
184
TDI
All
A11
34
183
TDO
All
A12
36
181
TMS
All
B1
143
2
TCK
All
C3
2
239
VCCINT
All
A9, B6, C5, G3,
G12, M5, M9, N6
10, 15, 25, 57, 84, 94,
99, 126
16, 32, 43, 77, 88, 104,
137, 148, 164, 198,
214, 225
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Table 2: Virtex Pinout Tables (Chip-Scale and QFP Packages) (Continued)
Pin Name
VCCO
Device
All
CS144
Banks 0 and 1:
A2, A13, D7
Banks 2 and 3:
B12, G11, M13
TQ144
No I/O Banks in this
package:
1, 17, 37, 55, 73, 92,
109, 128
Banks 4 and 5:
N1, N7, N13
PQ/HQ240
No I/O Banks in this
package:
15, 30, 44, 61, 76, 90,
105, 121, 136, 150, 165,
180, 197, 212, 226, 240
Banks 6 and 7:
B2, G2, M2
VREF, Bank 0
XCV50
C4, D6
5, 13
218, 232
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device
and all smaller devices
listed in the same
package.)
XCV100/150
... + B4
... + 7
... + 229
XCV200/300
N/A
N/A
... + 236
XCV400
N/A
N/A
... + 215
XCV600
N/A
N/A
... + 230
XCV800
N/A
N/A
... + 222
XCV50
A10, B8
22, 30
191, 205
XCV100/150
... + D9
... + 28
... + 194
XCV200/300
N/A
N/A
... + 187
XCV400
N/A
N/A
... + 208
XCV600
N/A
N/A
... + 193
XCV800
N/A
N/A
... + 201
XCV50
D11, F10
42, 50
157, 171
XCV100/150
... + D13
... + 44
... + 168
XCV200/300
N/A
N/A
... + 175
XCV400
N/A
N/A
... + 154
XCV600
N/A
N/A
... + 169
XCV800
N/A
N/A
... + 161
Within each bank, if
input reference voltage
is not required, all
VREF pins are general
I/O.
VREF, Bank 1
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device
and all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all
VREF pins are general
I/O.
VREF, Bank 2
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device
and all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all
VREF pins are general
I/O.
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Table 2: Virtex Pinout Tables (Chip-Scale and QFP Packages) (Continued)
Pin Name
VREF, Bank 3
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device
and all smaller devices
listed in the same
package.)
Device
CS144
TQ144
PQ/HQ240
XCV50
H11, K12
60, 68
130, 144
XCV100/150
... + J10
... + 66
... + 133
XCV200/300
N/A
N/A
... + 126
XCV400
N/A
N/A
... + 147
XCV600
N/A
N/A
... + 132
XCV800
N/A
N/A
... + 140
XCV50
L8, L10
79, 87
97, 111
XCV100/150
... + N10
... + 81
... + 108
XCV200/300
N/A
N/A
... + 115
XCV400
N/A
N/A
... + 94
XCV600
N/A
N/A
... + 109
XCV800
N/A
N/A
... + 101
XCV50
L4, L6
96, 104
70, 84
XCV100/150
... + N4
... + 102
... + 73
XCV200/300
N/A
N/A
... + 66
XCV400
N/A
N/A
... + 87
XCV600
N/A
N/A
... + 72
XCV800
N/A
N/A
... + 80
Within each bank, if
input reference voltage
is not required, all
VREF pins are general
I/O.
VREF, Bank 4
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device
and all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all
VREF pins are general
I/O.
VREF, Bank 5
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device
and all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all
VREF pins are general
I/O.
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Table 2: Virtex Pinout Tables (Chip-Scale and QFP Packages) (Continued)
Pin Name
VREF, Bank 6
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device
and all smaller devices
listed in the same
package.)
Device
CS144
TQ144
PQ/HQ240
XCV50
H2, K1
116, 123
36, 50
XCV100/150
... + J3
... + 118
... + 47
XCV200/300
N/A
N/A
... + 54
XCV400
N/A
N/A
... + 33
XCV600
N/A
N/A
... + 48
XCV800
N/A
N/A
... + 40
XCV50
D4, E1
133, 140
9, 23
XCV100/150
... + D2
... + 138
... + 12
XCV200/300
N/A
N/A
... + 5
XCV400
N/A
N/A
... + 26
XCV600
N/A
N/A
... + 11
XCV800
N/A
N/A
... + 19
All
A1, B9, B11, C7,
D5, E4, E11, F1,
G10, J1, J12, L3,
L5, L7, L9, N12
9, 18, 26, 35, 46, 54, 64,
75, 83, 91, 100, 111, 120,
129, 136, 144,
1, 8, 14, 22, 29, 37, 45, 51,
59, 69, 75, 83, 91, 98, 106,
112, 119, 129, 135, 143,
151, 158, 166, 172, 182,
190, 196, 204, 211, 219,
227, 233
Within each bank, if
input reference voltage
is not required, all
VREF pins are general
I/O.
VREF, Bank 7
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device
and all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all
VREF pins are general
I/O.
GND
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Table 3: Virtex Pinout Tables (BGA)
Pin Name
Device
BG256
BG352
BG432
BG560
GCK0
All
Y11
AE13
AL16
AL17
GCK1
All
Y10
AF14
AK16
AJ17
GCK2
All
A10
B14
A16
D17
GCK3
All
B10
D14
D17
A17
M0
All
Y1
AD24
AH28
AJ29
M1
All
U3
AB23
AH29
AK30
M2
All
W2
AC23
AJ28
AN32
CCLK
All
B19
C3
D4
C4
PROGRAM
All
Y20
AC4
AH3
AM1
DONE
All
W19
AD3
AH4
AJ5
INIT
All
U18
AD2
AJ2
AH5
BUSY/DOUT
All
D18
E4
D3
D4
D0/DIN
All
C19
D3
C2
E4
D1
All
E20
G1
K4
K3
D2
All
G19
J3
K2
L4
D3
All
J19
M3
P4
P3
D4
All
M19
R3
V4
W4
D5
All
P19
U4
AB1
AB5
D6
All
T20
V3
AB3
AC4
D7
All
V19
AC3
AG4
AJ4
WRITE
All
A19
D5
B4
D6
CS
All
B18
C4
D5
A2
TDI
All
C17
B3
B3
D5
TDO
All
A20
D4
C4
E6
TMS
All
D3
D23
D29
B33
TCK
All
A1
C24
D28
E29
DXN
All
W3
AD23
AH27
AK29
DXP
All
V4
AE24
AK29
AJ28
Module 4 of 4
6
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Production Product Specification
Product Obsolete/Under Obsolescence
R
Virtex™ 2.5 V Field Programmable Gate Arrays
Table 3: Virtex Pinout Tables (BGA) (Continued)
Pin Name
VCCINT
Notes:
• Superset includes all pins,
including the ones in bold
type. Subset excludes pins in
bold type.
• In BG352, for XCV300 all the
VCCINT pins in the superset
must be connected. For
XCV150/200, VCCINT pins in
the subset must be
connected, and pins in bold
type can be left unconnected
(these unconnected pins
cannot be used as user I/O.)
• In BG432, for
XCV400/600/800 all VCCINT
pins in the superset must be
connected. For XCV300,
VCCINT pins in the subset
must be connected, and pins
in bold type can be left
unconnected (these
unconnected pins cannot be
used as user I/O.)
• In BG560, for XCV800/1000
all VCCINT pins in the
superset must be connected.
For XCV400/600, VCCINT
pins in the subset must be
connected, and pins in bold
type can be left unconnected
(these unconnected pins
cannot be used as user I/O.)
Device
BG256
BG352
BG432
BG560
XCV50/100
C10, D6,
D15, F4,
F17, L3,
L18, R4,
R17, U6,
U15, V10
N/A
N/A
N/A
XCV150/200/300
Same as
above
A20, C14,
D10, J24,
K4, P2, P25,
V24, W2,
AC10, AE14,
AE19,
A10, A17, B23,
C14, C19, K3,
K29, N2, N29,
T1, T29, W2,
W31, AB2,
AB30, AJ10,
AJ16, AK13,
AK19, AK22,
N/A
B16, D12,
L1, L25,
R23, T1,
AF11, AF16
XCV400/600/800/1000
N/A
N/A
B26, C7, F1,
F30, AE29, AF1,
AH8, AH24
Same as above
A21, B14, B18,
B28, C24, E9,
E12, F2, H30,
J1, K32, N1,
N33, U5, U30,
Y2, Y31, AD2,
AD32, AG3,
AG31, AK8,
AK11, AK17,
AK20, AL14,
AL27, AN25,
B12, C22, M3,
N29, AB2,
AB32, AJ13,
AL22
VCCO, Bank 0
All
D7, D8
A17, B25,
D19
A21, C29, D21
A22, A26, A30,
B19, B32
VCCO, Bank 1
All
D13, D14
A10, D7,
D13
A1, A11, D11
A10, A16, B13,
C3, E5
VCCO, Bank 2
All
G17, H17
B2, H4, K1
C3, L1, L4
B2, D1, H1, M1,
R2
VCCO, Bank 3
All
N17, P17
P4, U1, Y4
AA1, AA4, AJ3
V1, AA2, AD1,
AK1, AL2
VCCO, Bank 4
All
U13, U14
AC8, AE2,
AF10
AH11, AL1,
AL11
AM2, AM15,
AN4, AN8, AN12
VCCO, Bank 5
All
U7, U8
AC14, AC20,
AF17
AH21, AJ29,
AL21
AL31, AM21,
AN18, AN24,
AN30
VCCO, Bank 6
All
N4, P4
U26, W23,
AE25
AA28, AA31,
AL31
W32, AB33,
AF33, AK33,
AM32
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Production Product Specification
www.xilinx.com
1-800-255-7778
Module 4 of 4
7
Product Obsolete/Under Obsolescence
R
Virtex™ 2.5 V Field Programmable Gate Arrays
Table 3: Virtex Pinout Tables (BGA) (Continued)
Pin Name
Device
BG256
BG352
BG432
BG560
VCCO, Bank 7
All
G4, H4
G23, K26,
N23
A31, L28, L31
C32, D33, K33,
N32, T33
VREF, Bank 0
XCV50
A8, B4
N/A
N/A
N/A
XCV100/150
... + A4
A16,C19,
C21
N/A
N/A
XCV200/300
... + A2
... + D21
B19, D22, D24,
D26
N/A
XCV400
N/A
N/A
... + C18
A19, D20,
(VREF pins are listed
incrementally. Connect all
pins listed for both the
required device and all
smaller devices listed in the
same package.)
Within each bank, if input
reference voltage is not
required, all VREF pins are
general I/O.
VREF, Bank 1
(VREF pins are listed
incrementally. Connect all
pins listed for both the
required device and all
smaller devices listed in the
same package.)
Within each bank, if input
reference voltage is not
required, all VREF pins are
general I/O.
VREF, Bank 2
(VREF pins are listed
incrementally. Connect all
pins listed for both the
required device and all
smaller devices listed in the
same package.)
Within each bank, if input
reference voltage is not
required, all VREF pins are
general I/O.
Module 4 of 4
8
D26, E23, E27
XCV600
N/A
N/A
... + C24
... + E24
XCV800
N/A
N/A
... + B21
... + E21
XCV1000
N/A
N/A
N/A
... + D29
XCV50
A17, B12
N/A
N/A
N/A
XCV100/150
... + B15
B6, C9,
N/A
N/A
A13, B7,
N/A
C12
XCV200/300
... + B17
... + D6
C6, C10
XCV400
N/A
N/A
... + B15
A6, D7,
D11, D16, E15
XCV600
N/A
N/A
... + D10
... + D10
XCV800
N/A
N/A
... + B12
... + D13
XCV1000
N/A
N/A
N/A
... + E7
XCV50
C20, J18
N/A
N/A
N/A
XCV100/150
... + F19
E2, H2,
N/A
N/A
E2, G3,
N/A
M4
XCV200/300
... + G18
... + D2
J2, N1
XCV400
N/A
N/A
... + R3
G5, H4,
L5, P4, R1
XCV600
N/A
N/A
... + H1
... + K5
XCV800
N/A
N/A
... + M3
... + N5
XCV1000
N/A
N/A
N/A
... + B3
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Production Product Specification
Product Obsolete/Under Obsolescence
R
Virtex™ 2.5 V Field Programmable Gate Arrays
Table 3: Virtex Pinout Tables (BGA) (Continued)
Pin Name
VREF, Bank 3
(VREF pins are listed
incrementally. Connect all
pins listed for both the
required device and all
smaller devices listed in the
same package.)
Within each bank, if input
reference voltage is not
required, all VREF pins are
general I/O.
VREF, Bank 4
(VREF pins are listed
incrementally. Connect all
pins listed for both the
required device and all
smaller devices listed in the
same package.)
Within each bank, if input
reference voltage is not
required, all VREF pins are
general I/O.
VREF, Bank 5
(VREF pins are listed
incrementally. Connect all
pins listed for both the
required device and all
smaller devices listed in the
same package.)
Within each bank, if input
reference voltage is not
required, all VREF pins are
general I/O.
VREF, Bank 6
(VREF pins are listed
incrementally. Connect all
pins listed for both the
required device and all
smaller devices listed in the
same package.)
Within each bank, if input
reference voltage is not
required, all VREF pins are
general I/O.
DS003-4 (v4.0) March 1, 2013
Production Product Specification
Device
BG256
BG352
BG432
BG560
XCV50
M18, V20
N/A
N/A
N/A
XCV100/150
... + R19
R4, V4, Y3
N/A
N/A
XCV200/300
... + P18
... + AC2
V2, AB4, AD4,
AF3
N/A
XCV400
N/A
N/A
... + U2
V4, W5,
AD3, AE5, AK2
XCV600
N/A
N/A
... + AC3
... + AF1
XCV800
N/A
N/A
... + Y3
... + AA4
XCV1000
N/A
N/A
N/A
... + AH4
XCV50
V12, Y18
N/A
N/A
N/A
XCV100/150
... + W15
AC12, AE5,
AE8,
N/A
N/A
XCV200/300
... + V14
... + AE4
AJ7, AL4, AL8,
AL13
N/A
XCV400
N/A
N/A
... + AK15
AL7, AL10,
AL16, AM4,
AM14
XCV600
N/A
N/A
... + AK8
... + AL9
XCV800
N/A
N/A
... + AJ12
... + AK13
XCV1000
N/A
N/A
N/A
... + AN3
XCV50
V9, Y3
N/A
N/A
N/A
XCV100/150
... + W6
AC15, AC18,
N/A
N/A
AJ18, AJ25,
N/A
AD20
XCV200/300
... + V7
... + AE23
AK23, AK27
XCV400
N/A
N/A
... + AJ17
AJ18, AJ25,
AL20, AL24,
AL29
XCV600
N/A
N/A
... + AL24
... + AM26
XCV800
N/A
N/A
... + AH19
... + AN23
XCV1000
N/A
N/A
N/A
... + AK28
XCV50
M2, R3
N/A
N/A
N/A
XCV100/150
... + T1
R24, Y26,
AA25,
N/A
N/A
XCV200/300
... + T3
... + AD26
V28, AB28,
AE30, AF28
N/A
XCV400
N/A
N/A
... + U28
V29, Y32, AD31,
AE29, AK32
XCV600
N/A
N/A
... + AC28
... + AE31
XCV800
N/A
N/A
... + Y30
... + AA30
XCV1000
N/A
N/A
N/A
... + AH30
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Module 4 of 4
9
Product Obsolete/Under Obsolescence
R
Virtex™ 2.5 V Field Programmable Gate Arrays
Table 3: Virtex Pinout Tables (BGA) (Continued)
Pin Name
VREF, Bank 7
(VREF pins are listed
incrementally. Connect all
pins listed for both the
required device and all
smaller devices listed in the
same package.)
Within each bank, if input
reference voltage is not
required, all VREF pins are
general I/O.
Device
BG256
BG352
BG432
BG560
XCV50
G3, H1
N/A
N/A
N/A
XCV100/150
... + D1
D26, G26,
N/A
N/A
F28, F31,
N/A
L26
XCV200/300
... + B2
... + E24
J30, N30
XCV400
N/A
N/A
... + R31
E31, G31, K31,
P31, T31
XCV600
N/A
N/A
... + J28
... + H32
XCV800
N/A
N/A
... + M28
... + L33
XCV1000
N/A
N/A
N/A
... + D31
GND
All
C3, C18,
D4, D5,
D9, D10,
D11,
D12,
D16,
D17, E4,
E17, J4,
J17, K4,
K17, L4,
L17, M4,
M17, T4,
T17, U4,
U5, U9,
U10,
U11,
U12,
U16,
U17, V3,
V18
A1, A2, A5,
A8, A14,
A19, A22,
A25, A26,
B1, B26, E1,
E26, H1,
H26, N1,
P26, W1,
W26, AB1,
AB26, AE1,
AE26, AF1,
AF2, AF5,
AF8, AF13,
AF19, AF22,
AF25, AF26
A2, A3, A7, A9,
A14, A18, A23,
A25, A29, A30,
B1, B2, B30,
B31, C1, C31,
D16, G1, G31,
J1, J31, P1, P31,
T4, T28, V1,
V31, AC1, AC31,
AE1, AE31,
AH16, AJ1,
AJ31, AK1, AK2,
AK30, AK31,
AL2, AL3, AL7,
AL9 AL14, AL18
AL23, AL25,
AL29, AL30
A1, A7, A12,
A14, A18, A20,
A24, A29, A32,
A33, B1, B6, B9,
B15, B23, B27,
B31, C2, E1,
F32, G2, G33,
J32, K1, L2,
M33, P1, P33,
R32, T1, V33,
W2, Y1, Y33,
AB1, AC32,
AD33, AE2,
AG1, AG32,
AH2, AJ33,
AL32, AM3,
AM7, AM11,
AM19, AM25,
AM28, AM33,
AN1, AN2, AN5,
AN10, AN14,
AN16, AN20,
AN22, AN27,
AN33
GND (1)
All
J9, J10,
J11, J12,
K9, K10,
K11, K12,
L9, L10,
L11, L12,
M9, M10,
M11, M12
N/A
N/A
N/A
No Connect
All
N/A
N/A
N/A
C31, AC2, AK4,
AL3
Notes:
1. 16 extra balls (grounded) at package center.
Module 4 of 4
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Production Product Specification
Product Obsolete/Under Obsolescence
R
Virtex™ 2.5 V Field Programmable Gate Arrays
Table 4: Virtex Pinout Tables (Fine-Pitch BGA)
Pin Name
Device
FG256
FG456
FG676
FG680
GCK0
All
N8
W12
AA14
AW19
GCK1
All
R8
Y11
AB13
AU22
GCK2
All
C9
A11
C13
D21
GCK3
All
B8
C11
E13
A20
M0
All
N3
AB2
AD4
AT37
M1
All
P2
U5
W7
AU38
M2
All
R3
Y4
AB6
AT35
CCLK
All
D15
B22
D24
E4
PROGRAM
All
P15
W20
AA22
AT5
DONE
All
R14
Y19
AB21
AU5
INIT
All
N15
V19
Y21
AU2
BUSY/DOUT
All
C15
C21
E23
E3
D0/DIN
All
D14
D20
F22
C2
D1
All
E16
H22
K24
P4
D2
All
F15
H20
K22
P3
D3
All
G16
K20
M22
R1
D4
All
J16
N22
R24
AD3
D5
All
M16
R21
U23
AG2
D6
All
N16
T22
V24
AH1
D7
All
N14
Y21
AB23
AR4
WRITE
All
C13
A20
C22
B4
CS
All
B13
C19
E21
D5
TDI
All
A15
B20
D22
B3
TDO
All
B14
A21
C23
C4
TMS
All
D3
D3
F5
E36
TCK
All
C4
C4
E6
C36
DXN
All
R4
Y5
AB7
AV37
DXP
All
P4
V6
Y8
AU35
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Production Product Specification
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1-800-255-7778
Module 4 of 4
11
Product Obsolete/Under Obsolescence
R
Virtex™ 2.5 V Field Programmable Gate Arrays
Table 4: Virtex Pinout Tables (Fine-Pitch BGA) (Continued)
Pin Name
Device
FG256
FG456
FG676
FG680
VCCINT
All
C3, C14, D4,
D13, E5,
E12, M5,
M12, N4,
N13, P3,
P14
E5, E18, F6,
F17, G7, G8, G9,
G14, G15, G16,
H7, H16, J7,
J16, P7, P16,
R7, R16, T7, T8,
T9, T14, T15,
T16, U6, U17,
V5, V18
G7, G20, H8, H19,
J9, J10, J11, J16,
J17, J18, K9, K18,
L9, L18, T9, T18,
U9, U18, V9, V10,
V11, V16, V17,
V18, W8, W19, Y7,
Y20
AD5, AD35,
AE5, AE35, AL5,
AL35, AM5,
AM35, AR8,
AR9, AR15,
AR16, AR24,
AR25, AR31,
AR32, E8, E9,
E15, E16, E24,
E25, E31, E32,
H5, H35, J5,
J35, R5, R35,
T5, T35
VCCO, Bank 0
All
E8, F8
F7, F8, F9, F10
G10, G11
H9, H10, H11,
H12, J12, J13
E26, E27, E29,
E30, E33, E34
VCCO, Bank 1
All
E9, F9
F13, F14, F15,
F16, G12, G13
H15, H16, H17,
H18, J14, J15
E6, E7, E10,
E11, E13, E14
VCCO, Bank 2
All
H11, H12
G17, H17, J17,
K16, K17, L16
J19, K19, L19,
M18, M19, N18
F5, G5, K5, L5,
N5, P5
VCCO, Bank 3
All
J11, J12
M16, N16, N17,
P17, R17, T17
P18, R18, R19,
T19, U19, V19
AF5, AG5, AN5,
AK5, AJ5, AP5
VCCO, Bank 4
All
L9. M9
T12, T13, U13,
U14, U15, U16,
V14, V15, W15,
W16, W17, W18
AR6, AR7,
AR10, AR11,
AR13, AR14
VCCO, Bank 5
All
L8, M8
T10, T11, U7,
U8, U9, U10
V12, V13,
W9,W10, W11,
W12
AR26, AR27,
AR29, AR30,
AR33, AR34
VCCO, Bank 6
All
J5, J6
M7, N6, N7, P6,
R6, T6
P9, R8, R9, T8,
U8, V8
AF35, AG35,
AJ35, AK35,
AN35, AP35
VCCO, Bank 7
All
H5, H6
G6, H6, J6, K6,
K7, L7
J8, K8, L8, M8,
M9, N9
F35, G35, K35,
L35, N35, P35
VREF, Bank 0
XCV50
B4, B7
N/A
N/A
N/A
XCV100/150
... + C6
A9, C6, E8
N/A
N/A
XCV200/300
... + A3
... + B4
N/A
N/A
XCV400
N/A
N/A
A12, C11, D6, E8,
G10
XCV600
N/A
N/A
... + B7
A33, B28, B30,
C23, C24, D33
XCV800
N/A
N/A
... + B10
... + A26
XCV1000
N/A
N/A
N/A
... + D34
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device and
all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all VREF
pins are general I/O.
Module 4 of 4
12
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1-800-255-7778
DS003-4 (v4.0) March 1, 2013
Production Product Specification
Product Obsolete/Under Obsolescence
R
Virtex™ 2.5 V Field Programmable Gate Arrays
Table 4: Virtex Pinout Tables (Fine-Pitch BGA) (Continued)
Pin Name
Device
FG256
FG456
FG676
FG680
XCV50
B9, C11
N/A
N/A
N/A
XCV100/150
... + E11
A18, B13, E14
N/A
N/A
XCV200/300
... + A14
... + A19
N/A
N/A
XCV400
N/A
N/A
A14, C20, C21,
D15, G16
N/A
XCV600
N/A
N/A
... + B19
B6, B8, B18,
D11, D13, D17
XCV800
N/A
N/A
... + A17
... + B14
XCV1000
N/A
N/A
N/A
... + B5
XCV50
F13, H13
N/A
N/A
N/A
XCV100/150
... + F14
F21, H18, K21
N/A
N/A
XCV200/300
... + E13
... + D22
N/A
N/A
XCV400
N/A
N/A
F24, H23, K20,
M23, M26
N/A
XCV600
N/A
N/A
... + G26
G1, H4, J1, L2,
V5, W3
XCV800
N/A
N/A
... + K25
... + N1
XCV1000
N/A
N/A
N/A
... + D2
XCV50
K16, L14
N/A
N/A
N/A
XCV100/150
... + L13
N21, R19, U21
N/A
N/A
XCV200/300
... + M13
... + U20
N/A
N/A
XCV400
N/A
N/A
R23, R25, U21,
W22, W23
N/A
XCV600
N/A
N/A
... + W26
AC1, AJ2, AK3,
AL4, AR1, Y1
XCV800
N/A
N/A
... + U25
... + AF3
XCV1000
N/A
N/A
N/A
... + AP4
VREF, Bank 1
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device and
all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all VREF
pins are general I/O.
VREF, Bank 2
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device and
all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all VREF
pins are general I/O.
VREF, Bank 3
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device and
all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all VREF
pins are general I/O.
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Virtex™ 2.5 V Field Programmable Gate Arrays
Table 4: Virtex Pinout Tables (Fine-Pitch BGA) (Continued)
Pin Name
VREF, Bank 4
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device and
all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all VREF
pins are general I/O.
VREF, Bank 5
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device and
all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all VREF
pins are general I/O.
VREF, Bank 6
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device and
all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all VREF
pins are general I/O.
Module 4 of 4
14
Device
FG256
FG456
FG676
FG680
XCV50
P9, T12
N/A
N/A
N/A
XCV100/150
... + T11
AA13, AB16,
AB19
N/A
N/A
XCV200/300
... + R13
... + AB20
N/A
N/A
XCV400
N/A
N/A
AC15, AD18,
AD21, AD22,
AF15
N/A
XCV600
N/A
N/A
... + AF20
AT19, AU7,
AU17, AV8,
AV10, AW11
XCV800
N/A
N/A
... + AF17
... + AV14
XCV1000
N/A
N/A
N/A
... + AU6
XCV50
T4, P8
N/A
N/A
N/A
XCV100/150
... + R5
W8, Y10, AA5
N/A
N/A
XCV200/300
... + T2
... + Y6
N/A
N/A
XCV400
N/A
N/A
AA10, AB8, AB12,
AC7, AF12
N/A
XCV600
N/A
N/A
... + AF8
AT27, AU29,
AU31, AV35,
AW21, AW23
XCV800
N/A
N/A
... + AE10
... + AT25
XCV1000
N/A
N/A
N/A
... + AV36
XCV50
J3, N1
N/A
N/A
N/A
XCV100/150
... + M1
N2, R4, T3
N/A
N/A
XCV200/300
... + N2
... + Y1
N/A
N/A
XCV400
N/A
N/A
AB3, R1, R4, U6,
V5
N/A
XCV600
N/A
N/A
... + Y1
AB35, AD37,
AH39, AK39,
AM39, AN36
XCV800
N/A
N/A
... + U2
... + AE39
XCV1000
N/A
N/A
N/A
... + AT39
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Table 4: Virtex Pinout Tables (Fine-Pitch BGA) (Continued)
Pin Name
Device
FG256
FG456
FG676
FG680
XCV50
C1, H3
N/A
N/A
N/A
XCV100/150
... + D1
E2, H4, K3
N/A
N/A
XCV200/300
... + B1
... + D2
N/A
N/A
XCV400
N/A
N/A
F4, G4, K6, M2,
M5
N/A
XCV600
N/A
N/A
... + H1
E38, G38, L36,
N36, U36, U38
XCV800
N/A
N/A
... + K1
... + N38
XCV1000
N/A
N/A
N/A
... + F36
All
A1, A16, B2,
B15, F6, F7,
F10, F11,
G6, G7, G8,
G9, G10,
G11, H7,
H8, H9, H10,
J7, J8, J9,
J10, K6, K7,
K8, K9, K10,
K11, L6, L7,
L10, L11,
R2, R15, T1,
T16
A1, A22, B2,
B21, C3, C20,
J9, J10, J11,
J12, J13, J14,
K9, K10, K11,
K12, K13, K14,
L9, L10, L11,
L12, L13, L14,
M9, M10, M11,
M12, M13, M14,
N9, N10, N11,
N12, N13, N14,
P9, P10, P11,
P12, P13, P14,
Y3, Y20, AA2,
AA21, AB1,
AB22
A1, A26, B2, B9,
B14, B18, B25,
C3, C24, D4, D23,
E5, E22, J2, J25,
K10, K11, K12,
K13, K14, K15,
K16, K17, L10,
L11, L12, L13,
L14, L15, L16,
L17, M10, M11,
M12, M13, M14,
M15, M16, M17,
N2, N10, N11,
N12, N13, N14,
N15, N16, N17,
P10, P11, P12,
P13, P14, P15,
P16, P17, P25,
R10, R11, R12,
R13, R14, R15,
R16, R17, T10,
T11, T12, T13,
T14, T15, T16,
T17, U10, U11,
U12, U13, U14,
U15, U16, U17,
V2, V25, AB5,
AB22, AC4, AC23,
AD3, AD24, AE2,
AE9, AE13, AE18,
AE25, AF1, AF26
A1, A2, A3, A37,
A38, A39, AA5,
AA35, AH4,
AH5, AH35,
AH36, AR5,
AR12, AR19,
AR20, AR21,
AR28, AR35,
AT4, AT12, AT20,
AT28, AT36,
AU1, AU3, AU20,
AU37, AU39,
AV1, AV2, AV38,
AV39, AW1,
AW2, AW3,
AW37, AW38,
AW39, B1, B2,
B38, B39, C1,
C3, C20, C37,
C39, D4, D12,
D20, D28, D36,
E5, E12, E19,
E20, E21, E28,
E35, M4, M5,
M35, M36, W5,
W35, Y3, Y4, Y5,
Y35, Y36, Y37
VREF, Bank 7
(VREF pins are listed
incrementally. Connect
all pins listed for both
the required device and
all smaller devices
listed in the same
package.)
Within each bank, if
input reference voltage
is not required, all VREF
pins are general I/O.
GND
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Virtex™ 2.5 V Field Programmable Gate Arrays
Table 4: Virtex Pinout Tables (Fine-Pitch BGA) (Continued)
Pin Name
No Connect
Device
FG256
FG456
FG676
FG680
XCV800
N/A
N/A
A2, A3, A15, A25,
B1, B6, B11, B16,
B21, B24, B26,
C1, C2, C25, C26,
F2, F6, F21, F25,
L2, L25, N25, P2,
T2, T25, AA2,
AA6, AA21, AA25,
AD1, AD2, AD25,
AE1, AE3, AE6,
AE11, AE14,
AE16, AE21,
AE24, AE26, AF2,
AF24, AF25
N/A
XCV600
N/A
N/A
same as above
N/A
XCV400
N/A
N/A
... + A9, A10, A13,
A16, A24, AC1,
AC25, AE12,
AE15, AF3, AF10,
AF11, AF13,
AF14, AF16,
AF18, AF23, B4,
B12, B13, B15,
B17, D1, D25,
H26, J1, K26, L1,
M1, M25, N1, N26,
P1, P26, R2, R26,
T1, T26, U26, V1
N/A
XCV300
N/A
D4, D19, W4,
W19
N/A
N/A
XCV200
N/A
... + A2, A6, A12,
B11, B16, C2,
D1, D18, E17,
E19, G2, G22,
L2, L19, M2,
M21, R3, R20,
U3, U18, Y22,
AA1, AA3, AA11,
AA16, AB7,
AB12, AB21,
N/A
N/A
XCV150
N/A
... + A13, A14,
C8, C9, E13,
F11, H21, J1, J4,
K2, K18, K19,
M17, N1, P1, P5,
P22, R22, W13,
W15, AA9,
AA10, AB8,
AB14
N/A
N/A
(No-connect pins are
listed incrementally. All
pins listed for both the
required device and all
larger devices listed in
the same package are
no connects.)
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Virtex™ 2.5 V Field Programmable Gate Arrays
Pinout Diagrams
The following diagrams, CS144 Pin Function Diagram,
page 17 through FG680 Pin Function Diagram, page 27,
illustrate the locations of special-purpose pins on Virtex
FPGAs. Table 5 lists the symbols used in these diagrams.
The diagrams also show I/O-bank boundaries.
Table 5: Pinout Diagram Symbols
Symbol
Pin Function
Table 5: Pinout Diagram Symbols (Continued)
Symbol
❿, ❶, ❷
➉, ➀, ➁,
➂, ➃, ➄, ➅,
➆
Pin Function
M0, M1, M2
D0/DIN, D1, D2, D3, D4, D5, D6, D7
B
DOUT/BUSY
D
DONE
P
PROGRAM
VCCINT
I
INIT
Device-dependent VCCINT, n/c on smaller
devices
K
CCLK
W
WRITE
O
VCCO
S
CS
R
VREF
T
Boundary-scan Test Access Port
r
Device-dependent VREF, remains I/O on
smaller devices
+
Temperature diode, anode
–
Temperature diode, cathode
G
Ground
n
No connect
✳
General I/O
❄
Device-dependent general I/O, n/c on
smaller devices
V
v
Ø, 1, 2, 3
Global Clocks
CS144 Pin Function Diagram
Bank 1
1
2
3
4
5
6
7
8
9
10
11
12
13
Bank 0
Bank 7
GO✳ ✳✳ 3 2 ✳ V R T T O A
T O✳ r ✳ V ✳RG✳GO K B
✳ ✳ T R V ✳ G ✳ ✳W B ➉ ✳ C
✳ r ✳RGRO✳ r S R✳ r D
R ✳✳G
➀G➁✳ E
G ✳ ✳ ✳ CS144 R ➂ ✳ ✳ F
✳ O V ✳(Top view) G O V ✳ G
✳ R➃ ✳ H
✳R✳✳
G✳ r ✳
r ➅ G➄ J
R ✳✳✳✳✳Ø✳✳ ➆✳R✳ K
✳ ❶GRGRGR GR ✳ P I L
❿O✳✳ V ✳ 1 ✳ V ✳✳DO M
O❷ ✳ r ✳ V O✳✳ r ✳GO N
Bank 2
Bank 3
1
2
3
4
5
6
7
8
9
10
11
12
13
Bank 6
A
B
C
D
E
F
G
H
J
K
L
M
N
Bank 5
Bank 4
Figure 1: CS144 Pin Function Diagram
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144
143
142
141
140
139
138
137
136
135
134
133
132
131
130
129
128
127
126
125
124
123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
TQ144 Pin Function Diagram
O
T
✳
✳
R
✳
r
✳
G
V
✳
✳
R
✳
V
3
O
G
2
✳
✳
R
✳
✳
V
G
✳
r
✳
R
✳
W
S
T
G
T
G T ✳✳R ✳ r ✳G✳✳R ✳✳✳GO✳ V ✳✳R ✳✳G✳ r ✳R ✳✳✳ ❶G ❿O
Bank 7
Bank 6
Bank 5
Bank 0
TQ144
(Top view)
Bank 1
Bank 4
Bank 2
Bank 3
O K B ➉ ✳ R ✳ r ➀ G ➁ ✳ ✳ R ➂ ✳ ✳ G O ✳ V ✳➃ R ✳ ✳ ➄ G ➅ r ✳ R ✳ ➆ I P
❷ 108
✳
✳
✳
R
✳
r
✳
G
V
✳
✳
R
✳
V
1
O
G
Ø
✳
✳
R
✳
✳
V
G
✳
r
✳
R
✳
✳
✳
G
D
O
107
106
105
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
Figure 2: TQ144 Pin Function Diagram
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239
237
235
233
231
229
227
225
223
221
219
217
215
213
211
209
207
205
203
201
199
197
195
193
191
189
187
185
183
181
PQ240/HQ240 Pin Function Diagram
T ✳ ✳ G ✳ r G V ✳ ✳ G ✳ r 3 G ✳ ✳ R ✳ r ✳ O ✳ r R ✳ r W T T
O ✳ r ✳ R r ✳ O ✳ r ✳ R ✳ V O 2 r ✳ G ✳ ✳ V G r ✳ G ✳ ✳ S G
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
51
53
55
57
59
G
T
✳
✳
r
✳
✳
G
R
✳
r
r
✳
G
O
V
✳
✳
r
✳
✳
G
R
✳
✳
r
✳
✳
G
O
✳
V
r
✳
✳
R
G
✳
✳
r
✳
✳
V
O
G
✳
r
r
✳
R
G
✳
✳
r
✳
✳
✳
❶
G
❿
Bank 0
O
Bank 1
B
✳
✳
G
✳
Bank 7
Bank 2
PQ240/HQ240
(Top view)
Pins are shown staggered
for readability
Bank 6
Bank 3
Bank 5
Bank 4
K
179
➉
177
175
173
r
✳
R
r
r
➀
G
O
V
➁
✳
r
✳
✳
G
R
➂
✳
r
✳
✳
G
O
✳
V
r
✳
➃
R
G
✳
✳
r
✳
➄
V
O
G
➅
r
r
✳
R
G
✳
✳
r
✳
➆
I
P
O
171
169
167
165
163
161
159
157
155
153
151
149
147
145
143
141
139
137
135
133
131
129
127
125
123
121
61
63
65
67
69
71
73
75
77
79
81
83
85
87
89
91
93
95
97
99
101
103
105
107
109
111
113
115
117
119
❷ ✳ r ✳ R r ✳ O ✳ r ✳ R ✳ V O Ø r ✳ G ✳ ✳ V G r ✳ G ✳ ✳ ✳ D
O ✳ ✳ ✳ G ✳ r G V ✳ ✳ G ✳ r 1 G ✳ ✳ R ✳ r ✳ O ✳ r R ✳ r ✳ G
Figure 3: PQ240/HQ240 Pin Function Diagram
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2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
BG256 Pin Function Diagram
T
✳
✳
r
✳
✳
✳
R
✳
✳
✳
✳
✳
✳
✳
r
✳
✳
✳
❿
r
r
✳
✳
✳
✳
✳
✳
✳
✳
✳
R
✳
✳
✳
✳
✳
✳
❷
✳
✳
✳
G
T
✳
✳
R
✳
✳
✳
V
✳
✳
✳
R
r
❶
G
–
R
r
R
✳
G
G
V
O
O
G
G
G
G
O
O
V
G
G
+
✳
✳
✳
✳
✳
G
✳
✳
✳
V
✳ R✳
✳ ✳ ✳
✳ ✳ ✳
O O G
Bank 0
2
3
V
G
✳
✳
✳
G
✳ ✳ ✳
R✳ ✳
✳ ✳ ✳
G O O
Bank 1
✳
r
✳
V
✳
✳
✳
G
BG256
Bank 7
Bank 2
G
G
G
G
Bank 6
G
✳
✳
✳
V
✳
r
✳
G
G
G
G
G
G
G
G
G
G
G
G
(Top View)
Bank 5
O O G
r ✳ R
✳ ✳ ✳
✳ ✳ ✳
G
V
✳
1
G
✳
✳
Ø
Bank 3
Bank 4
G O O
R✳ r
✳ ✳ ✳
✳ ✳ ✳
V
✳
r
✳
G
✳
✳
✳
R
r
T
G
G
V
O
O
G
G
G
G
O
O
V
G
G
✳
✳
✳
✳
S
G
B
✳
✳
r
✳
R
✳
V
R
✳
r
✳
✳
I
G
✳
R
W T
K✳
➉ R
✳ ✳
✳ ➀
r ✳
➁✳
✳ ✳
➂✳
✳ ✳
✳ ✳
➃✳
✳ ✳
➄✳
r ✳
✳ ➅
✳ ✳
➆ R
D✳
✳ P
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
DS003_18_100300
Figure 4: BG256 Pin Function Diagram
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2
3
4
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6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
BG352 Pin Function Diagram
G G
G O
✳ ✳
✳ r
G R
✳ ✳
➀✳
G R
✳ ✳
O ✳
V ✳
✳ ✳
G ✳
✳V
✳ ✳
V ✳
O ✳
✳ ✳
GV
✳ ✳
✳ ✳
G ✳
✳ r
✳ I
G O
G G
✳ ✳ G
T ✳ ✳
K S✳
➉ T W
✳ B
✳ ✳
✳ ✳
✳ O
➁✳
✳V
✳ ✳
➂R
✳ ✳
✳ O
➃R
✳ ✳
✳ ➄
➅R
✳ ✳
R O
✳ ✳
✳ ✳
➆P ✳
D ✳ ✳
✳ r R
✳ ✳ G
✳
R
✳
r
✳
✳
✳
O
G
✳
✳
✳
✳
✳
R
✳
O
✳
✳
V
✳
✳
✳
✳
✳
✳
R
V
✳
✳
✳
O
G
2
V
3
✳
✳
✳
✳
Bank 1
R
V
✳
✳
O
✳
✳
✳
✳
✳
✳
✳
G
✳
R
O
V
✳
✳
✳
✳
✳
R
r
G
✳
✳
✳
Bank 0
Bank 2
Bank 7
BG352
(Top View)
Bank 3
Bank 6
Bank 4
✳
✳
✳
✳
✳
✳
✳
✳
O
✳
R
G
✳
✳
✳
✳
V
✳
✳
O
✳
✳
✳
V
Bank 5
R
✳
✳
✳
✳
✳
Ø
G
O
✳
V
1
R
✳
✳
✳
✳
✳
✳
V
✳
✳
✳
O
R
✳
✳
✳
✳
✳
V
G
O
R
✳
✳
✳
✳
✳
✳
✳
✳
✳
G
✳
✳
✳
T
✳
✳
O
✳
✳
✳
✳
✳
O
✳
V
✳
✳
✳
O
✳
✳
❶
❷
–
r
✳
✳
✳
T
✳
r
✳
✳
✳
V
✳
✳
✳
✳
✳
R
✳
✳
V
✳
✳
✳
✳
✳
❿
+
✳
G
O
✳
✳
✳
✳
✳
✳
✳
✳
V
✳
✳
V
✳
✳
✳
✳
✳
✳
R
✳
✳
✳
O
G
G
G
✳
R
G
✳
R
G
✳
O
R
✳
✳
G
✳
✳
O
✳
G
R
✳
G
✳
r
G
G
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
AD
AE
AF
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
AD
AE
AF
DS003_19_100600
Figure 5: BG352 Pin Function Diagram
DS003-4 (v4.0) March 1, 2013
Production Product Specification
www.xilinx.com
1-800-255-7778
Module 4 of 4
21
Product Obsolete/Under Obsolescence
R
Virtex™ 2.5 V Field Programmable Gate Arrays
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
BG432 Pin Function Diagram
O
G
G
✳
✳
V
G
r
G
✳
O
✳
R
G
✳
V
✳
G
✳
✳
O
➄
G
✳
G
V
✳
✳
G
G
O
G
G
➉
✳
R
✳
✳
✳
R
➁
✳
✳
V
✳
✳
✳
r
R
V
✳
✳
V
✳
✳
✳
✳
✳
✳
I
G
G
G
T
O
B
✳
✳
R
✳
✳
V
✳
r
✳
✳
r
✳
✳
✳
✳
r
✳
➅
r
✳
✳
R
✳
P
O
✳
G
✳
W
T
K
✳
✳
✳
✳
✳
➀
O
✳
✳
➂
✳
G
✳
➃
✳
✳
O
R
✳
R
✳
✳
➆
D
✳
✳
R
✳
✳
✳
S
✳
✳
R
✳
G
R
V
✳
✳
✳
✳
✳
G
✳
✳
✳
V
✳
R
r
O
✳
✳
O
✳
r
✳
✳
R
✳
✳
✳
G
✳
V
✳
✳
r
✳
✳
2
✳
✳
G
V
✳
✳
3
G
✳
r
✳
✳
R
V
✳
✳
✳
✳
✳
Bank 1
O
r
✳
O
✳
✳
✳
R
G
V
✳
✳
✳
✳
r
R
G
✳
✳
✳
✳
V
✳
R
✳
✳
✳
✳
Bank 0
Bank 2
Bank 7
BG432
(Top View)
Bank 3
Bank 6
Bank 4
✳
✳
✳
✳
✳
✳
✳
✳
✳
R
✳
G
V
✳
r
R
✳
✳
✳
G
✳
V
✳
✳
O
✳
✳
O
Bank 5
✳
r
✳
✳
✳
✳
V
R
✳
✳
✳
G
✳
✳
r
✳
G
V
1
Ø
✳
r
✳
✳
✳
R
✳
G
r
✳
V
✳
✳
✳
✳
✳
O
✳
✳
O
✳
✳
V
✳
✳
✳
R
G
V
✳
✳
r
✳
R
✳
G
✳
✳
✳
✳
–
✳
R
✳
✳
✳
✳
T
✳
R
✳
✳
r
✳
O
r
✳
✳
✳
G
r
R
✳
✳
O
R
r
✳
✳
R
✳
❿
❷
✳
✳
G
✳
O
T
✳
✳
✳
✳
✳
V
✳
✳
V
✳
✳
V
✳
✳
✳
✳
✳
✳
✳
✳
V
✳
✳
❶
O
+
G
G
G
✳
✳
✳
V
✳
✳
R
✳
✳
✳
R
✳
✳
✳
✳
✳
✳
r
✳
V
✳
✳
R
✳
✳
✳
✳
G
G
O
G
G
✳
✳
R
G
✳
G
✳
O
✳
✳
G
r
✳
✳
G
V
✳
O
✳
G
✳
G
✳
✳
✳
G
G
O
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
AD
AE
AF
AG
AH
AJ
AK
AL
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
AD
AE
AF
AG
AH
AJ
AK
AL
DS003_21_100300
Figure 6: BG432 Pin Function Diagram
Module 4 of 4
22
www.xilinx.com
1-800-255-7778
DS003-4 (v4.0) March 1, 2013
Production Product Specification
Product Obsolete/Under Obsolescence
R
Virtex™ 2.5 V Field Programmable Gate Arrays
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
BG560 Pin Function Diagram
G
G
✳
O
G
✳
✳
O
V
G
✳
O
V
G
R
G
✳
O
✳
G
✳
G
✳
O
✳
r
G
✳
✳
O
✳
P
G
S
O
G
✳
✳
V
G
✳
✳
✳
G
✳
✳
✳
O
✳
✳
✳
G
V
O
V
n
V
G
✳
✳
G
✳
R
O
O
G
✳ ✳ ✳ R G ✳ ✳ O ✳
r ✳ ✳ G ✳ ✳ G ✳ ✳
OK ✳ ✳ ✳ ✳ ✳ ✳ ✳
✳ B T W R ✳ ✳ r R
✳ ➉O T r ✳V ✳ ✳
✳ ✳ ✳
Bank 1
✳ ✳ R
✳ R ✳
✳ ✳ ✳
➀✳ r
Bank 2
✳ ➁R
V ✳ ✳
✳ ✳ r
➂R ✳
✳ ✳ ✳
✳ ✳ ✳
✳ ✳V
✳ R ✳
✳ ➃R
✳ ✳ ✳
✳ r ✳
✳ ✳ ➄
✳ ➅ ✳ Bank 3
R ✳ ✳
✳ ✳ R
✳ ✳ ✳
V ✳ ✳
Bank 4
✳ r I
✳ ➆D ✳ ✳ ✳ ✳ ✳ ✳
✳ n ✳ ✳ ✳V ✳ ✳V
n ✳ ✳ ✳ R ✳ r R ✳
G R ✳ ✳ G ✳ ✳ ✳ G
r O G ✳ ✳ O ✳ G ✳
G
V
✳
✳
V
✳
O
✳
r
✳
G
V
✳
✳
✳
✳
G
✳
✳
R
O
✳
✳
R
✳
3
✳
✳
2
✳
G
V
✳
✳
✳
R
O
✳
✳
✳
G
✳
✳
R
✳
V
✳
✳
✳
r
O
✳
V
✳
✳
✳ G ✳
G ✳ ✳
✳V ✳
✳ ✳ ✳
R r ✳
Bank 0
O
✳
✳
R
✳
✳
G
✳
✳
R
✳
V
✳
✳
✳
Bank 7
BG560
(Top View)
Bank 6
Bank 5
✳
✳
✳
✳
O
V
r
✳
✳
✳
✳
✳
V
R
G
✳
✳
✳
O
✳
✳
✳
R
✳
G
1
V
Ø
✳
✳
R
✳
✳
✳
O
✳
✳
✳
G
✳
✳
V
R
✳
G
✳
✳
✳
O
✳
✳
✳
V
✳
G
✳
✳
✳
✳
r
✳
✳
R
✳
O
R
✳
✳
G
V
✳
✳
✳
r
✳
✳
✳
V
✳
G
+
r
✳
G
✳
G
✳
✳
r
T
✳
✳
✳
✳
✳
✳
✳
V
✳
✳
✳
✳
R
✳
✳
✳
✳
✳
✳
R
✳
✳
✳
❿
–
R
✳
✳
O
✳
✳
✳
✳
✳
✳
V
✳
✳
✳
✳
✳
✳
✳
✳
V
✳
✳
✳
r
✳
✳
✳
✳
✳
✳
r
✳
❶
✳
✳
O
✳
G
n
r
R
✳
R
✳
✳
R
✳
✳
✳
R
✳
R
✳
✳
✳
V
✳
✳
✳
R
r
✳
V
✳
✳
✳
O
✳
✳
G
O
O
✳
✳
G
✳
r
G
V
✳
✳
O
✳
G
✳
✳
✳
O
R
✳
V
G
V
✳
✳
G
✳
✳
R
G
O
❷
G
T
✳
O
✳
✳
G
✳
✳
O
r
G
V
G
✳
O
✳
G
✳
G
✳
O
✳
G
✳
O
✳
✳
G
O
✳
G
G
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
AD
AE
AF
AG
AH
AJ
AK
AL
AM
AN
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
AD
AE
AF
AG
AH
AJ
AK
AL
AM
AN
DS003_22_100300
Figure 7: BG560 Pin Function Diagram
DS003-4 (v4.0) March 1, 2013
Production Product Specification
www.xilinx.com
1-800-255-7778
Module 4 of 4
23
Product Obsolete/Under Obsolescence
R
Virtex™ 2.5 V Field Programmable Gate Arrays
FG256 Pin Function Diagram
Bank 1
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
Bank 0
G✳ r ✳✳✳✳✳✳✳✳✳✳ r T G A
r G✳R✳✳R 3 R✳✳✳S T G✳ B
R ✳ V T ✳ r ✳ ✳ 2 ✳ R ✳W V B ✳ C
r ✳ T V ✳✳✳✳✳✳✳✳V ➉ K ✳ D
✳✳✳✳ V ✳✳OO✳ r V r ✳✳ ➀ E
✳✳✳✳✳GGOOGG✳R r ➁ ✳ F
✳✳✳✳✳GGGGGG✳✳✳✳➂ G
✳✳R ✳OOGGGGOOR ✳✳✳ H
✳ ✳ R ✳ O O G G G G O O ✳ ✳ ✳➃ J
✳✳✳✳✳GGGGGG✳✳✳✳R K
✳✳✳✳✳GGOOGG✳ r R ✳✳ L
r ✳✳✳ V ✳✳OO✳✳ V r ✳✳➄ M
R r ❿ V ✳✳✳Ø✳✳✳✳ V ➆ I ➅ N
✳❶ V + ✳✳✳RR✳✳✳✳V P ✳ P
✳G❷ – r ✳✳ 1 ✳✳✳✳ r DG✳ R
G r ✳R ✳✳✳✳✳✳ r R ✳✳✳G T
Bank 2
Bank 3
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
A
B
C
Bank 7 D
E
F
G
H
J
K
L
M
Bank 6 N
P
R
T
Bank 5
Bank 4
FG256
(Top view)
Figure 8: FG256 Pin Function Diagram
Module 4 of 4
24
www.xilinx.com
1-800-255-7778
DS003-4 (v4.0) March 1, 2013
Production Product Specification
Product Obsolete/Under Obsolescence
R
Virtex™ 2.5 V Field Programmable Gate Arrays
FG456 Pin Function Diagram
Bank 1
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
Bank 0
Bank 7
G❅ ✳✳✳❅ ✳✳R ✳ 2 ❅ ❅ ❅ ✳✳✳R r WT G A
✳G✳ r ✳✳✳✳✳✳❅ ✳R ✳✳❅ ✳✳✳ T G K B
✳❅G T ✳R✳❅ ❅ ✳ 3 ✳✳✳✳✳✳✳SGB ✳ C
❅ r T n ✳✳✳✳✳✳✳✳✳✳✳✳✳❅ n ➉ ✳ r D
✳R✳✳V ✳✳R✳✳✳✳❅ R✳✳❅ V ❅ ✳✳✳ E
✳✳✳✳✳ V OOOO❅ ✳OOOO V ✳✳✳R ✳ F
✳❅ ✳✳✳O V V V OOOO V V V O✳✳✳✳❅ G
VOR✳➁❅ ➀ H
✳✳✳R ✳O V
❅ ✳✳❅ ✳O V GGGGGG V O✳✳✳✳✳ J
✳❅ R ✳✳OO GGGGGG OO❅ ❅ ➂ R ✳ K
✳❅ ✳✳✳✳O GGGGGG O✳✳❅ ✳✳✳ L
✳❅ ✳✳✳✳O GGGGGG O❅ ✳✳✳❅ ✳ M
❅ R ✳✳✳OO GGGGGG OO✳✳✳ R➃ N
❅ ✳✳✳❅ O V GGGGGG V O✳✳✳✳❅ P
VO✳R❅➄ ❅ R
✳✳❅ R ✳O V
✳✳R ✳✳O V V V OOOO V V V O✳✳✳✳➅ T
✳✳❅ ✳ ❶V OOOO✳✳OOOO V ❅ ✳ r R ✳ U
✳✳✳✳V + ✳✳✳✳✳✳✳✳✳✳✳V I ✳✳✳ V
✳✳✳n ✳✳✳R ✳✳✳Ø❅ ✳❅ ✳✳✳n P ✳✳ W
r ✳G❷ – r ✳✳✳R 1 ✳✳✳✳✳✳✳DG ➆❅ Y
❅ G ❅ ✳ R ✳ ✳ ✳ ❅ ❅ ❅ ✳ R ✳ ✳ ❅ ✳ ✳ ✳ ✳ G ✳ AA
G ❿ ✳ ✳ ✳ ✳ ❅ ❅ ✳ ✳ ✳ ❅ ✳ ❅ ✳ R ✳ ✳ R r ❅ G AB
Bank 2
Bank 3
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
Bank 6
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
Bank 5
Bank 4
FG456
(Top view)
Figure 9: FG456 Pin Function Diagram
Notes:
Packages FG456 and FG676 are layout compatible.
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Virtex™ 2.5 V Field Programmable Gate Arrays
FG676 Pin Function Diagram
17
18
19
20
21
22
23
24
25
26
❄
G
✳
✳
✳
✳
❄
r
✳
✳
✳
✳
❄
n
✳
✳
✳
✳
✳
r
✳
✳
✳
✳
✳
V
O
O
O
O
✳
✳
O
O
O
O
✳
n
R
✳
S
n
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
R
✳
✳
✳
W
T
G
✳
✳
T
G
B
✳
✳
R
✳
✳
✳
R
✳
✳
R
✳
n
G
n
❄
✳
R
O
V
G
G
G
G
G
G
G
G
V
✳
G
✳
✳
✳
✳
✳
O
V
V
V
O
O
O
O
V
V
V
✳
✳
R
✳
✳
✳
✳
O
V
V
V
O
O
O
O
V
V
V
r
❄
✳
✳
✳
✳
✳
O
V
G
G
G
G
G
G
G
G
V
1
2
3
4
5
6
7
8
9
16
Bank 1
10
11
12
13
14
15
Bank 0
❶ V O O O O ✳ ✳ O O O O V ✳ ✳ R R ✳ ✳ r
V + ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ V I ✳ ✳ ✳ ✳ ✳
W
Bank 5
➉
✳
✳
✳
➁
✳
➂
R
✳
✳
✳
➀
✳
✳
✳
✳
✳
✳
✳
➃
✳
✳
✳ ➄ ✳
✳ ✳ ➅
P ✳ ✳ n
G ➆ ✳ ✳
✳ G ✳ ❄
R ✳ G n
✳ ✳ n G
✳ ❄ n n
✳
✳
✳
✳
n
G
Bank 2
Bank 3
Y
AA
AB
AC
AD
AE
AF
25
26
✳ ✳ ✳ n
✳ ✳ ✳ D
✳ ✳ ✳ ✳
R ✳ ✳ R
G ✳ ✳ n
❄ ✳ r ✳
23
24
✳ ✳ ✳
✳ ✳ ✳
R ✳ ✳
✳ ✳ ✳
❄ n ✳
R ❄ r
V
✳
✳
R
✳
✳
✳
✳
✳
✳
✳
✳
22
✳
✳
✳
✳
R
O
V
G
G
G
G
G
G
G
G
V
21
✳ ✳ 0
R 1 ✳
✳ ✳ ✳
✳ ✳ ✳
r n ❄ G n
❄ ❄ R ❄ ❄
R
✳
✳
✳
n
❄
✳
R
✳
✳
✳
O
O
G
G
G
G
G
G
G
G
O
❄
n
G
K
✳
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
✳ ✳ ✳
- R ✳
R ✳ ✳
✳ ✳ ✳
✳ ✳ G
✳ r ✳
R
G
✳
✳
✳
✳
✳
✳
O
G
G
G
G
G
G
G
G
O
20
✳ ✳
n ✳
✳ R
✳ ✳
❄
❄
2
✳
3
✳
✳
✳
O
G
G
G
G
G
G
G
G
O
G
n
n
✳
✳
n ✳
✳ r
✳ ❄
G ✳
r ❄
n ✳
❄ R
n ❄
G ❄
R ❄
n ❄
r ❄
G ✳
V
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
R
❄
✳
✳
✳
✳
✳
O
O
G
G
G
G
G
G
G
G
O
19
✳ ✳ ✳
✳ ✳ n
✳ G ❷
G ✳ ✳
n n G ❿ ✳ ✳
n G n ✳ ✳ n
G n ❄ ✳ ✳ ✳
r
✳
✳
❄
✳
n
R
✳
✳
✳
✳
O
V
G
G
G
G
G
G
G
G
V
18
✳ ✳ ✳ ✳ ✳ ✳
Y
AA
AB
AC
AD
AE
AF
✳
✳
✳
✳
R
✳
✳
V
O
O
O
O
✳
✳
O
O
O
O
17
W
R
R
✳
✳
✳
✳
✳
✳
✳
R
✳
✳
✳
✳
r
✳
✳
✳
✳
16
✳
n
✳
R
T
n
✳
✳
✳
R
✳
✳
✳
✳
✳
✳
R
R ✳
1
2
3
4
5
6
7
8
9
Bank 6
n
✳
✳
G
✳
n
R
G
n
❄
n
r
G
n
✳
G
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
G
T
✳
✳
✳
✳
✳
R
✳
✳
✳
✳
✳
G
n
n
❄
✳
✳
✳
r
❄
r
❄
❄
❄
❄
R
❄
✳
❄
10
11
12
13
14
15
Bank 7
n
G
n
✳
✳
✳
❄
✳
G
✳
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
Bank 4
FG676
(Top view)
fg676a
Figure 10: FG676 Pin Function Diagram
Notes:
Packages FG456 and FG676 are layout compatible.
Module 4 of 4
26
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R
Virtex™ 2.5 V Field Programmable Gate Arrays
FG680 Pin Function Diagram
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
M
N
P
14
✳
R
✳
✳
V
13
8
✳
✳
✳
✳
O
12
7
✳
R
✳
✳
O
11
6
✳
r
✳
S
G
O
O
V
V
O
O
9
5
G G ✳
G T W
➉ G T
r ✳ G
✳ B K
✳ ✳ ✳
✳ ✳ ✳
✳ ✳ R
✳ ✳ ✳
✳ ✳ ✳
R ✳ ✳
Bank 0
10
4
G
G
G
✳
✳
✳
R
✳
R
✳
✳
R
T
U
3
2
A
B
C
D
E
F
G
H
J
K
L
✳
✳
✳
✳
V
✳
✳
✳
✳
O
✳
✳
✳
R
O
✳
✳
✳
G
G
✳
✳
✳
R
O
✳
r
✳
✳
O
✳
✳
✳
✳
V
✳
✳
✳
✳
V
✳
✳
✳
R
✳
✳
R
✳
✳
✳
✳
✳
✳
✳
G
3
✳
G
G
G
✳
✳
✳
2
G
✳
✳
✳
✳
✳
✳
✳
R
✳
✳
✳
✳
R
✳
V
✳
✳
✳
✳
V
r
✳
✳
✳
O
✳
✳
✳
✳
O
✳
R
✳
G
G
✳
✳
✳
✳
O
✳
R
✳
✳
O
✳
✳
✳
✳
V
✳
✳
✳
✳
V
R
✳
✳
R
O
✳
✳
✳
r
O
✳
✳
✳
✳
G
O
O
V
V
O
O
✳
✳
T
G
T
r
✳
✳
✳
✳
R
G
✳
G
✳
✳
✳
✳
✳
✳
✳
✳
G
G
✳
✳
R
✳
R
✳
✳
✳
✳
G
G
G
✳
✳
✳
✳
✳
✳
✳
✳
A
B
C
D
E
F
G
H
J
K
L
✳ ✳ ✳ G G
r ✳ ✳ ✳ O
✳ ✳ ➁ ➀ O
G G ✳ ✳ ✳
O R ✳ r ✳
O ✳ ✳ ✳ ✳
M
N
P
➂ ✳ ✳ ✳ V
✳ ✳ ✳ ✳ V
✳ ✳ ✳ ✳ ✳
V ✳ ✳ ✳ ✳
V ✳ ✳ ✳ ✳
✳ R ✳ R ✳
R
T
U
V
✳ ✳ ✳ ✳ R
✳ ✳ ✳ ✳ ✳
V
W
✳ ✳ R ✳ G
G ✳ ✳ ✳ ✳
W
Y
R ✳ G G G
AA
✳ ✳ ✳ ✳ G
AB
AC
AD
AE
AF
AG
✳
R
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳ ✳ ✳
✳ ✳ ✳
➃ ✳ V
✳ ✳ V
r ✳ O
✳ ✳ O
✳
✳
✳
✳
✳
✳
R
R
✳
✳
✳
✳
✳
✳
✳
R
✳
✳
✳
✳
✳
AH
AJ
AK
AL
AM
AN
Bank 3 AP
AR
FG680
( Top View)
Bank 7
Bank 2
➄
➅ ✳ ✳ G G
✳
✳
R
✳
✳
r
➆
O
O
V
V
O
O
G O O V V O O G O O V V ✳ ✳ G G G ✳ ✳ V V O O G O O V V O O
G G G ✳ ✳
Y
G ✳ ✳ ✳ ✳
AA
✳
✳
✳
✳
✳
✳
✳
✳
R
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
r
✳
✳
AB
AC
AD
AE
AF
AG
G
O
O
V
V
O
O
G
G
✳
✳
✳
✳
R
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
✳
R
✳
R
✳
R
✳
✳
✳
AH
AJ
AK
AL
AM
AN
AP Bank 6
AR
✳ ✳ ✳ G P ✳ ✳ ✳ ✳ ✳ ✳ G ✳ ✳ ✳ ✳ ✳ ✳ R G ✳ ✳ ✳ ✳ r ✳ R G ✳ ✳ ✳ ✳ ✳ ✳
AU
G
❷ G ❿ ✳ r
+ ✳ G ❶ G
AU
AV
AW
G G ✳ ✳ ✳ ✳ ✳ R ✳ R ✳ ✳ ✳ r ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ R r
G G
G G G ✳ ✳ ✳ ✳ ✳ ✳ ✳ R ✳ ✳ ✳ ✳ ✳ ✳ ✳ 0 ✳ R ✳ R ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ G G G
AV
AW
Bank 4
AT
39
38
37
36
-
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
r R ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ ✳ R ✳ ✳ G ✳ 1 ✳ ✳ ✳ ✳ ✳ ✳ R ✳ R ✳ ✳ ✳
6
5
4
G ✳ D
3
1
I
Bank 7
R
✳
V
V
O
O
AT
2
Bank 2
1
Bank 1
Bank 5
Note: AA3, AA4, and AB2 are in Bank 2
Note: AA37 is in Bank 7
fg680_12a
Figure 11: FG680 Pin Function Diagram
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Virtex™ 2.5 V Field Programmable Gate Arrays
Revision History
Date
Version
Revision
11/98
1.0
01/99-02/99
1.2-1.3
05/99
1.4
Addition of package drawings and specifications.
05/99
1.5
Replaced FG 676 & FG680 package drawings.
07/99
1.6
Changed Boundary Scan Information and changed Figure 11, Boundary Scan Bit
Sequence. Updated IOB Input & Output delays. Added Capacitance info for different I/O
Standards. Added 5 V tolerant information. Added DLL Parameters and waveforms and
new Pin-to-pin Input and Output Parameter tables for Global Clock Input to Output and
Setup and Hold. Changed Configuration Information including Figures 12, 14, 17 & 19.
Added device-dependent listings for quiescent currents ICCINTQ and ICCOQ. Updated
IOB Input and Output Delays based on default standard of LVTTL, 12 mA, Fast Slew Rate.
Added IOB Input Switching Characteristics Standard Adjustments.
09/99
1.7
Speed grade update to preliminary status, Power-on specification and Clock-to-Out
Minimums additions, "0" hold time listing explanation, quiescent current listing update, and
Figure 6 ADDRA input label correction. Added TIJITCC parameter, changed TOJIT to TOPHASE.
01/00
1.8
Update to speed.txt file 1.96. Corrections for CRs 111036,111137, 112697, 115479,
117153, 117154, and 117612. Modified notes for Recommended Operating Conditions
(voltage and temperature). Changed Bank information for VCCO in CS144 package on p.43.
01/00
1.9
Updated DLL Jitter Parameter table and waveforms, added Delay Measurement
Methodology table for different I/O standards, changed buffered Hex line info and
Input/Output Timing measurement notes.
03/00
2.0
New TBCKO values; corrected FG680 package connection drawing; new note about status
of CCLK pin after configuration.
05/00
2.1
Modified "Pins not listed..." statement. Speed grade update to Final status.
05/00
2.2
Modified Table 18.
09/00
2.3
10/00
2.4
04/02/01
2.5
04/19/01
2.6
07/19/01
2.7
07/19/02
03/01/13
Initial Xilinx release.
Both versions updated package drawings and specs.
•
•
•
•
•
•
•
•
Added XCV400 values to table under Minimum Clock-to-Out for Virtex Devices.
Corrected Units column in table under IOB Input Switching Characteristics.
Added values to table under CLB SelectRAM Switching Characteristics.
Corrected pinout info for devices in the BG256, BG432, and BG560 pkgs in Table 18.
Corrected BG256 Pin Function Diagram.
Revised minimums for Global Clock Set-Up and Hold for LVTTL Standard, with DLL.
Converted file to modularized format. See section Virtex Data Sheet, below.
Corrected pinout information for FG676 device in Table 4. (Added AB22 pin.)
2.8
•
•
•
Clarified VCCINT pinout information and added AE19 pin for BG352 devices in Table 3.
Changed pinouts listed for BG352 XCV400 devices in banks 0 thru 7.
Changed pinouts listed for GND in TQ144 devices (see Table 2).
4.0
The products listed in this data sheet are obsolete. See XCN10016 for further information.
Virtex Data Sheet
The Virtex Data Sheet contains the following modules:
•
•
DS003-1, Virtex 2.5V FPGAs:
Introduction and Ordering Information (Module 1)
DS003-2, Virtex 2.5V FPGAs:
Functional Description (Module 2)
Module 4 of 4
28
•
•
DS003-3, Virtex 2.5V FPGAs:
DC and Switching Characteristics (Module 3)
DS003-4, Virtex 2.5V FPGAs:
Pinout Tables (Module 4)
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Production Product Specification