XC5202-6PC84C Xilinx Inc, XC5202-6PC84C Datasheet - Page 29
XC5202-6PC84C
Manufacturer Part Number
XC5202-6PC84C
Description
IC FPGA 64 CLB'S 84-PLCC
Manufacturer
Xilinx Inc
Series
XC5200r
Datasheet
1.XC5206-5PQ208C.pdf
(73 pages)
Specifications of XC5202-6PC84C
Number Of Logic Elements/cells
256
Number Of Labs/clbs
64
Number Of I /o
65
Number Of Gates
3000
Voltage - Supply
4.75 V ~ 5.25 V
Mounting Type
Surface Mount
Operating Temperature
0°C ~ 85°C
Package / Case
84-LCC (J-Lead)
Dc
9629
Lead Free Status / RoHS Status
Contains lead / RoHS non-compliant
Total Ram Bits
-
Other names
122-1131
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Company:
Part Number:
XC5202-6PC84C
Manufacturer:
XILINX
Quantity:
1 980
Company:
Part Number:
XC5202-6PC84C
Manufacturer:
XILINX
Quantity:
1 980
Part Number:
XC5202-6PC84C
Manufacturer:
XILINX/赛灵思
Quantity:
20 000
When the UCLK_SYNC option is enabled, the user can
externally hold the open-drain DONE output Low, and thus
stall all further progress in the start-up sequence until
DONE is released and has gone High. This option can be
used to force synchronization of several FPGAs to a com-
mon user clock, or to guarantee that all devices are suc-
cessfully configured before any I/Os go active.
If either of these two options is selected, and no user clock
is specified in the design or attached to the device, the chip
could reach a point where the configuration of the device is
complete and the Done pin is asserted, but the outputs do
not become active. The solution is either to recreate the
bitstream specifying the start-up clock as CCLK, or to sup-
ply the appropriate user clock.
Start-up Sequence
The Start-up sequence begins when the configuration
memory is full, and the total number of configuration clocks
received since INIT went High equals the loaded value of
the length count.
The next rising clock edge sets a flip-flop Q0, shown in
Figure
outputs of this register can be programmed to control three
events.
• The release of the open-drain DONE output
• The change of configuration-related pins to the user
• The termination of the global Set/Reset initialization of
The DONE pin can also be wire-ANDed with DONE pins of
other FPGAs or with other external signals, and can then
be used as input to bit Q3 of the start-up register. This is
called “Start-up Timing Synchronous to Done In” and is
selected by either CCLK_SYNC or UCLK_SYNC.
When DONE is not used as an input, the operation is called
“Start-up Timing Not Synchronous to DONE In,” and is
selected by either CCLK_NOSYNC or UCLK_NOSYNC.
As a configuration option, the start-up control register
beyond Q0 can be clocked either by subsequent CCLK
pulses or from an on-chip user net called STARTUP.CLK.
These signals can be accessed by placing the STARTUP
library symbol.
Start-up from CCLK
If CCLK is used to drive the start-up, Q0 through Q3 pro-
vide the timing. Heavy lines in
timing, which is compatible with XC2000 and XC3000
devices using early DONE and late Reset. The thin lines
indicate all other possible timing options.
Start-up from a User Clock (STARTUP.CLK)
When, instead of CCLK, a user-supplied start-up clock is
selected, Q1 is used to bridge the unknown phase relation-
November 5, 1998 (Version 5.2)
function, activating all IOBs.
all CLB and IOB storage elements.
26. Q0 is the leading bit of a 5-bit shift register. The
R
Product Obsolete or Under Obsolescence
Figure 25
show the default
XC5200 Series Field Programmable Gate Arrays
DONE Goes High to Signal End of Configuration
In all configuration modes except Express mode,
XC5200-Series devices read the expected length count
from the bitstream and store it in an internal register. The
length count varies according to the number of devices and
the composition of the daisy chain.
counts the number of CCLKs during configuration.
Two conditions have to be met in order for the DONE pin to
go high:
• the chip's internal memory must be full, and
• the configuration length count must be met, exactly .
This is important because the counter that determines
when the length count is met begins with the very first
CCLK, not the first one after the preamble.
Therefore, if a stray bit is inserted before the preamble, or
the data source is not ready at the time of the first CCLK,
the internal counter that holds the number of CCLKs will be
one ahead of the actual number of data bits read. At the
end of configuration, the configuration memory will be full,
but the number of bits in the internal counter will not match
the expected length count.
As a consequence, a Master mode device will continue to
send out CCLKs until the internal counter turns over to
zero, and then reaches the correct length count a second
time. This will take several seconds [2
— which is sometimes interpreted as the device not config-
uring at all.
If it is not possible to have the data ready at the time of the
first CCLK, the problem can be avoided by increasing the
number in the length count by the appropriate value.
In Express mode, there is no length count. The DONE pin
for each device goes High when the device has received its
quota of configuration data. Wiring the DONE pins of sev-
eral devices together delays start-up of all devices until all
are fully configured.
Note that DONE is an open-drain output and does not go
High unless an internal pull-up is activated or an external
pull-up is attached. The internal pull-up is activated as the
default by the bitstream generation software.
Release of User I/O After DONE Goes High
By default, the user I/O are released one CCLK cycle after
the DONE pin goes High. If CCLK is not clocked after
DONE goes High, the outputs remain in their initial state —
3-stated, with a 20 k
ship between CCLK and the user clock. This arbitration
causes an unavoidable one-cycle uncertainty in the timing
of the rest of the start-up sequence.
- 100 k
pull-up. The delay from
24
Each device also
CCLK period]
7-111
7
Related parts for XC5202-6PC84C
Image
Part Number
Description
Manufacturer
Datasheet
Request
R
Part Number:
Description:
IC - FPGA SPEED GRADE 5 COM TEMP
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC FPGA 64 CLB'S 100-PQFP
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC CPLD .8K 36MCELL 44-VQFP
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC CPLD 72MCRCELL 10NS 44VQFP
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC CPLD 1.6K 72MCELL 64-VQFP
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC CR-II CPLD 64MCELL 44-VQFP
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC CPLD 1.6K 72MCELL 100-TQFP
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC CR-II CPLD 64MCELL 56-BGA
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC CPLD 72MCRCELL 7.5NS 44VQFP
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC CR-II CPLD 64MCELL 100-VQFP
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC CPLD 1.6K 72MCELL 100-TQFP
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC CPLD 72MCRCELL 7.5NS 64VQFP
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC CPLD 1.6K 72MCELL 100-TQFP
Manufacturer:
Xilinx Inc
Datasheet:
Part Number:
Description:
IC CPLD 1.5K 64MCELL HP 44-VQFP
Manufacturer:
Xilinx Inc