XCV2000E-8FG1156C Xilinx Inc, XCV2000E-8FG1156C Datasheet - Page 13
XCV2000E-8FG1156C
Manufacturer Part Number
XCV2000E-8FG1156C
Description
IC FPGA 1.8V C-TEMP 1156-BGA
Manufacturer
Xilinx Inc
Series
Virtex™-Er
Datasheet
1.XCV200E-6CS144C.pdf
(233 pages)
Specifications of XCV2000E-8FG1156C
Number Of Logic Elements/cells
43200
Number Of Labs/clbs
9600
Total Ram Bits
655360
Number Of I /o
804
Number Of Gates
2541952
Voltage - Supply
1.71 V ~ 1.89 V
Mounting Type
Surface Mount
Operating Temperature
0°C ~ 85°C
Package / Case
1156-BBGA
Lead Free Status / RoHS Status
Contains lead / RoHS non-compliant
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Dedicated Routing
Some classes of signal require dedicated routing resources to
maximize performance. In the Virtex-E architecture, dedi-
cated routing resources are provided for two classes of signal.
•
•
•
Global Clock Distribution
Virtex-E provides high-speed, low-skew clock distribution
through the global routing resources described above. A
typical clock distribution net is shown in
DS022-2 (v2.8) January 16, 2006
Production Product Specification
Horizontal routing resources are provided for on-chip
3-state buses. Four partitionable bus lines are provided
per CLB row, permitting multiple buses within a row, as
shown in
Two dedicated nets per CLB propagate carry signals
vertically to the adjacent CLB.Global Clock Distribution
Network
DLL Location
Figure 9: Global Clock Distribution Network
Global Clock Rows
R
Figure
GCLKBUF3
GCLKPAD3
GCLKBUF1
GCLKPAD1
8.
CLB
Figure 8: BUFT Connections to Dedicated Horizontal Bus LInes
GCLKBUF2
GCLKBUF0
GCLKPAD0
GCLKPAD2
Figure
Global Clock Column
CLB
XCVE_009
9.
www.xilinx.com
CLB
Clock Routing
Clock Routing resources distribute clocks and other signals
with very high fanout throughout the device. Virtex-E
devices include two tiers of clock routing resources referred
to as global and local clock routing resources.
•
•
Four global buffers are provided, two at the top center of the
device and two at the bottom center. These drive the four
global nets that in turn drive any clock pin.
Four dedicated clock pads are provided, one adjacent to
each of the global buffers. The input to the global buffer is
selected either from these pads or from signals in the gen-
eral purpose routing.
Digital Delay-Locked Loops
There are eight DLLs (Delay-Locked Loops) per device,
with four located at the top and four at the bottom,
Figure
between the clock input pad and the internal clock input pins
throughout the device. Each DLL can drive two global clock
networks.The DLL monitors the input clock and the distrib-
uted clock, and automatically adjusts a clock delay element.
Additional delay is introduced such that clock edges arrive
at internal flip-flops synchronized with clock edges arriving
at the input.
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,
and can double the clock or divide the clock by 1.5, 2, 2.5, 3,
4, 5, 8, or 16.
The 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 global nets can be driven only by
global buffers. There are four global buffers, one for
each global net.
The 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 local resources are
more flexible than the global resources since they are
not restricted to routing only to clock pins.
Virtex™-E 1.8 V Field Programmable Gate Arrays
10. The DLLs can be used to eliminate skew
CLB
buft_c.eps
Tri-State
Lines
Module 2 of 4
7
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