XILINX SC9500XV

0
XC9500XV Family High-Performance
CPLD
R
DS049 (v2.0) January 15, 2001
0
6
Advance Product Specification
Features
Family Overview
•
The XC9500XV family is a 2.5V CPLD family targeted for
high-performance, low-voltage applications in leading-edge
communications and computing systems, where high
device reliability and low power dissipation is important.
Each XC9500XV device supports in-system programming
(ISP) and the full IEEE 1149.1 (JTAG) boundary-scan,
allowing superior debug and design iteration capability for
small form-factor packages. The XC9500XV family is
designed to work closely with the Xilinx Spartan-XL and Virtex FPGA families, allowing system designers to partition
logic optimally between fast interface circuitry and high-density general purpose logic. As shown in Table 1, logic density of the XC9500XV devices ranges from 800 to 6400
usable gates with 36 to 288 registers, respectively. Multiple
package options and associated I/O capacity are shown in
Table 2. The XC9500XV family members are fully pin-compatible, allowing easy design migration across multiple density options in a given package footprint.
•
•
Optimized for high-performance 2.5V systems
-
3.5 ns pin-to-pin logic delays
-
Small footprint packages including VQFPs, TQFPs
and CSPs (Chip Scale Package)
-
Lower power operation
-
Multi-voltage operation
-
FastFLASH technology
Advanced system features
-
In-system programmable
-
Output banking (XC95144XV, XC95288XV)
-
Superior pin-locking and routability with
FastCONNECT II™ switch matrix
-
Extra wide 54-input Function Blocks
-
Up to 90 product-terms per macrocell with
individual product-term allocation
-
Local clock inversion with three global and one
product-term clocks
-
Individual output enable per output pin with local
inversion
-
Input hysteresis on all user and boundary-scan pin
inputs
-
Bus-hold circuitry on all user pin inputs
-
Full IEEE Standard 1149.1 boundary-scan (JTAG)
support on all devices
Four pin-compatible device densities
-
36 to 288 macrocells, with 800 to 6400 usable
gates
•
Fast concurrent programming
•
Slew rate control on individual outputs
•
Enhanced data security features
•
Excellent quality and reliability
The XC9500XV architectural features address the requirements of in-system programmability. Enhanced pin-locking
capability avoids costly board rework. In-system programming throughout the full commercial operating range and a
high programming endurance rating provide worry-free
reconfigurations of system field upgrades. Extended data
retention supports longer and more reliable system operating life.
Advanced system features include output slew rate control
and user-programmable ground pins to help reduce system
noise. Each user pin is compatible with 3.3V, 2.5V, and 1.8V
inputs, and the outputs may be configured for 3.3V, 2.5V, or
1.8V operation. The XC9500XV device exhibits symmetric
full 2.5V output voltage swing to allow balanced rise and fall
times.
Architecture Description
-
10,000 program/erase cycles endurance rating
-
20 year data retention
•
Pin-compatible with 3.3V core XC9500XL family in
common package footprints
•
Hot Plugging capability
Each XC9500XV device is a subsystem consisting of multiple Function Blocks (FBs) and I/O Blocks (IOBs) fully interconnected by the FastCONNECT II switch matrix. The IOB
provides buffering for device inputs and outputs. Each FB
provides programmable logic capability with extra wide 54
inputs and 18 outputs. The FastCONNECT II switch matrix
connects all FB outputs and input signals to the FB inputs.
For each FB, up to 18 outputs (depending on package
pin-count) and associated output enable signals drive
directly to the IOBs. See Figure 1.
© 2001 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.
DS049 (v2.0) January 15, 2001
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1
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XC9500XV Family High-Performance CPLD
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3
JTAG Port
JTAG
Controller
In-System Programming Controller
54
Function
Block 1
18
I/O
Macrocells
1 to 18
I/O
FastCONNECT II Switch Matrix
I/O
I/O
I/O
Blocks
I/O
I/O
I/O
54
Function
Block 2
18
Macrocells
1 to 18
54
Function
Block 3
18
Macrocells
1 to 18
I/O
3
I/O/GCK
54
Function
Block N
1
18
I/O/GSR
Macrocells
1 to 18
2 or 4
I/O/GTS
DS049_01_041400
Figure 1: XC9500XV Architecture
Note: Function block outputs (indicated by the bold lines) drive the I/O blocks directly.
Table 1: XC9500XV Device Family
2
XC9536XV
XC9572XV
XC95144XV
XC95288XV
Macrocells
36
72
144
288
Usable Gates
800
1,600
3,200
6,400
Registers
36
72
144
288
TPD (ns)
3.5
4
4
5
TSU (ns)
2.8
3.1
3.1
3.7
TCO (ns)
1.8
2.0
2.0
2.5
fSYSTEM (MHz)
278
250
250
222
Output Banks
1
1
2
4
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XC9500XV Family High-Performance CPLD
Table 2: XC9500XV Packages and User I/O Pins (not including four dedicated JTAG pins)
XC9536XV
XC9572XV
XC95144XV
XC95288XV
44-pin PLCC
34
34
-
-
44-pin VQFP
34
34
-
-
100-pin TQFP
-
72
81
-
144-pin TQFP
-
-
117
117
208-pin PQFP
-
-
-
168
48-pin CSP
36
38
-
-
144-pin CSP
-
-
117
-
280-pin CSP
-
-
-
192
256-pin FBGA
-
-
-
192
Function Block
Logic within the FB is implemented using a sum-of-products
representation. Fifty-four inputs provide 108 true and complement signals into the programmable AND-array to form
90 product terms. Any number of these product terms, up to
the 90 available, can be allocated to each macrocell by the
product term allocator.
Each Function Block, as shown in Figure 2 is comprised of
18 independent macrocells, each capable of implementing
a combinatorial or registered function. The FB also receives
global clock, output enable, and set/reset signals. The FB
generates 18 outputs that drive the FastCONNECT II switch
matrix. These 18 outputs and their corresponding output
enable signals also drive the IOB.
Macrocell 1
Programmable
AND-Array
From
FastCONNECT II
Switch Matrix
Product
Term
Allocators
18
54
18
18
To FastCONNECT II
Switch Matrix
OUT
To I/O Blocks
PTOE
Macrocell 18
1
3
Global Global
Set/Reset Clocks
DS049_02_041400
Figure 2: XC9500XV Function Block
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XC9500XV Family High-Performance CPLD
Macrocell
Each XC9500XV macrocell may be individually configured
for a combinatorial or registered function. The macrocell
and associated FB logic is shown in Figure 3.
Five direct product terms from the AND-array are available
for use as primary data inputs (to the OR and XOR gates) to
implement combinatorial functions, or as control inputs
including clock, clock enable, set/reset, and output enable.
54
The product term allocator associated with each macrocell
selects how the five direct terms are used.
The macrocell register can be configured as a D-type or
T-type flip-flop, or it may be bypassed for combinatorial
operation. Each register supports both asynchronous set
and reset operations. During power-up, all user registers
are initialized to the user-defined preload state (default to 0
if unspecified).
Global
Set/Reset
Global
Clocks
3
Additional
Product
Terms
(from other
macrocells)
Product Term Set
1
0
To
FastCONNECTII
Switch Matrix
S
D/T Q
Product
Term
Allocator
EC
Product Term Clock Enable
R
Product Term Clock
Product Term Reset
OUT
Product Term OE
PTOE
To
I/O Blocks
Additional
Product
Terms
(from other
macrocells)
DS049_03_041400
Figure 3: XC9500XV Macrocell Within Function Block
Note: See Figure 8 for additional clock enable details
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XC9500XV Family High-Performance CPLD
All global control signals are available to each individual
macrocell, including clock, set/reset, and output enable signals. As shown in Figure 4, the macrocell register clock
originates from either of three global clocks or a product
term clock. Both true and complement polarities of the
selected clock source can be used within each macrocell. A
GSR input is also provided to allow user registers to be set
to a user-defined state.
Macrocell
Product Term Set
S
D/T
EC
Product Term Clock
R
Product Term Reset
I/O/GSR
Global Set/Reset
I/O/GCK1
Global Clock 1
I/O/GCK2
Global Clock 2
I/O/GCK3
Global Clock 3
DS049_04_041400
Figure 4: Macrocell Clock and Set/Reset Capability
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XC9500XV Family High-Performance CPLD
Product Term Allocator
The product term allocator controls how the five direct product terms are assigned to each macrocell. For example, all
five direct terms can drive the OR function as shown in
Figure 5.
Note that the incremental delay affects only the product
terms in other macrocells. The timing of the direct product
terms is not changed..
Product Term
Allocator
Product Term
Allocator
Macrocell
Product Term
Logic
Product Term
Allocator
DS049_05_041400
Figure 5: Macrocell Logic Using Direct Product Term
The product term allocator can re-assign other product
terms within the FB to increase the logic capacity of a macrocell beyond five direct terms. Any macrocell requiring
additional product terms can access uncommitted product
terms in other macrocells within the FB. Up to 15 product
terms can be available to a single macrocell with only a
small incremental delay of TPTA, as shown in Figure 6.
Macrocell Logic
With 15
Product Terms
Product Term
Allocator
DS049_06_041400
Figure 6: Product Term Allocation With 15 Product
Terms
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XC9500XV Family High-Performance CPLD
The product term allocator can re-assign product terms
from any macrocell within the FB by combining partial sums
of products over several macrocells, as shown in Figure 7.
In this example, the incremental delay is only 2*TPTA. All 90
product terms are available to any macrocell, with a maximum incremental delay of 8*TPTA.
Product Term
Allocator
Macrocell Logic
With 2
Product Terms
Product Term
Allocator
Product Term
Allocator
Macrocell Logic
With 18
Product Terms
Product Term
Allocator
DS049_07 _041400
Figure 7: Product Term Allocation Over Several
Macrocells
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XC9500XV Family High-Performance CPLD
The internal logic of the product term allocator is shown in
Figure 8.
From Upper
Macrocell
To Upper
Macrocell
Product Term
Allocator
Product Term Set
Global Set/Reset
1
0
S
D/T Q
CE
Global Clocks
R
Product Term Clock
Product Term Reset
Global Set/Reset
Product Term OE
From Lower
Macrocell
To Lower
Macrocell
DS049_08_041400
Figure 8: Product Term Allocator Logic
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XC9500XV Family High-Performance CPLD
FastCONNECT II Switch Matrix
The FastCONNECT II Switch Matrix connects signals to the
FB inputs, as shown in Figure 9. All IOB outputs (corresponding to user pin inputs) and all FB outputs drive the
FastCONNECT II
Switch Matrix
FastCONNECT II matrix. Any of these (up to a fan-in limit of
54) may be selected to drive each FB with a uniform delay.
Function Block
I/O Block
(54)
18
D/T Q
I/O
Function Block
I/O Block
(54)
18
D/T Q
I/O
DS049_09_041400
Figure 9: FastCONNECT II Switch Matrix
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XC9500XV Family High-Performance CPLD
I/O Block
The I/O Block (IOB) interfaces between the internal logic
and the device user I/O pins. Each IOB includes an input
buffer, output driver, output enable selection multiplexer,
and user programmable ground control. See Figure 10 for
details.
To other
Macrocells
I/O Block
To FastCONNECT
Switch Matrix
Macrocell
Bus-Hold
I/O
OUT
(Inversion in
AND-array)
Product Term OE
1
PTOE
UserProgrammable
Ground
0
Slew Rate
Control
I/O/GTS1
Global OE 1
I/O/GTS2
Global OE 2
I/O/GTS3
Global OE 3
I/O/GTS4
Global OE 4
Available in XC95144XV
and XC95288XV
DS049_10_041400
Figure 10: I/O Block and Output Enable Capability
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XC9500XV Family High-Performance CPLD
The input buffer is compatible with 3.3V CMOS, 2.5V
CMOS, and 1.8V CMOS signals. The input buffer uses the
internal 2.5V voltage supply (VCCINT) to ensure that the
input thresholds are constant and do not vary with the
VCCIO voltage. Each input buffer provides input hysteresis
(50 mV typical) to help reduce system noise for input signals
with slow rise or fall edges.
Each output driver is designed to provide fast switching with
minimal power noise. All output drivers in the device may be
configured for driving either 3.3V, 2.5V, or 1.8V CMOS levels by connecting the device output voltage supply (VCCIO)
to a 3.3V, 2.5V, or 1.8V voltage supply. Figure 11(a) shows
how the XC9500XV device can be used in a 2.5V only system.
Each output driver can also be configured for slew-rate limited operation. Output edge rates may be slowed down to
reduce system noise (with an additional time delay of
TSLEW) under user control. See Figure 12.
The output enable may be generated from one of four
options: a product term signal from the macrocell, any of the
global output enable signals (GTS), always “1”, or always
“0”. There are two global output enables for devices with 72
or fewer macrocells, and four global output enables for
devices with 144 or more macrocells. Any selected output
enable signal may be inverted locally at each pin output to
provide maximum design flexibility.
Each IOB provides user programmable ground pin capability. This allows device I/O pins to be configured as additional
ground pins in order to force otherwise unused pins to a low
voltage state, as well as provide for additional device
grounding capability. This grounding of the pin is achieved
by internal logic that forces a logic Low output regardless of
the internal macrocell signal, so the internal macrocell logic
is unaffected by the programmable ground pin capability.
Each IOB also provides for bus-hold circuitry that is active
during valid user operation. The bus-hold feature eliminates
the need to tie unused pins either High or Low by holding
the last known state of the input until the next input signal is
present. The bus-hold circuit drives back the same state via
a nominal resistance (RBH) of 50K ohms. See Figure 13.
Note: The bus-hold output will drive no higher than VCCIO to
prevent overdriving signals when interfacing to 2.5V components.
When the device is not in valid user operation, the bus-hold
circuit defaults to an equivalent 50K ohm pull-up resistor in
order to provide a known repeatable device state. This
occurs when the device is in the erased state, in programming mode, in JTAG INTEST mode, or during initial
power-up. A pull-down resistor (1K ohm) may be externally
added to any pin to override the default R BH resistance to
force a Low state during power-up or any of these other
modes.
2.5V
3.3V CMOS or
2.5V
VCCINT
3.3V
0V
2.5V CMOS
IN
VCCIO1
VCCIO2
XC9500XV
CPLD
OUT
3.3V CMOS or
3.3V
VCCINT VCCIO1 VCCIO2
1.8V CMOS
3.3V
1.8V
2.5V CMOS
2.5V
OUT1
0V
2.5V CMOS or
0V
2.5V
1.8V
0V
IN
XC9500XV
CPLD
3.3V CMOS
2.5V
0V
3.3V
OUT2
0V
GND
1.8V CMOS
GND
0V
1.8V
(a)
0V
(b)
DS049_11_041400
Figure 11: XC9500XV Devices in (a) 2.5V only and (b) Mixed 3.3V/2.5V/1.8V Systems
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XC9500XV Family High-Performance CPLD
Output
Voltage
Output
Voltage
VCCIO
Standard
Slew-Rate Limited
Slew-Rate Limited
TSLEW
TSLEW
1.2V
1.2V
Standard
Time
0
Time
0
(b)
(a)
DS049_12_041400
Figure 12: Output Slew-Rate Control For (a) Rising and (b) Falling Outputs
Set to PIN
during valid user
operation
Output Banking
XC95288XV and XC95144XV devices are designed with a
split-rail I/O structure. This permits the utilization of multiple
output drive levels for systems able to operate best in that
environment. The output partitioning is by function blocks
(FB). With this arrangement, designers can have some sets
of outputs driving to 2.5V and others set to 1.8V. Naturally, it
is possible to tie all rails to a single output voltage and get all
outputs driving to that level. Should designs be migrated
from one density to another in the same package, care
should be taken to remember the voltage assignments chosen at the outset to assure consistency (Figure 14).
Drive to
VCCIO Level
0
PIN
RBH
I/O
VCCINTs
DS049_13_041400
Figure 13: Bus-Hold Logic
VCCIO1
VCCIO2
GNDs
DS049_14_011501
Figure 14: Split Rail VCC Output Power Connections in
XC95144XV and XC95288XV Devices
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XC9500XV Family High-Performance CPLD
Mixed Voltage
The I/Os on each XC9500XV device are fully 3.3V tolerant
even though the core power supply is 2.5V. This allows 3.3V
CMOS signals to connect directly to the XC9500XV inputs
without damage. In addition, the 2.5V VCCINT power supply
can be applied before or after 2.5V signals are applied to
the I/Os. In mixed 3.3V/2.5V/1.8V systems, the user pins,
the core power supply (VCCINT), and the output power supply (VCCIO) may have power applied in any order. This
makes the XC9500XV devices immune to power supply
sequencing problems (see Figure 11b).
Xilinx proprietary ESD circuitry and high impedance initial
state permit hot plugging cards using XC9500XV CPLDs.
Pin-Locking Capability
The capability to lock the user defined pin assignments during design iteration depends on the ability of the architecture to adapt to unexpected changes. The XC9500XV
devices incorporate architectural features that enhance the
ability to accept design changes while maintaining the same
pinout.
The XC9500XV architecture provides for superior pin-locking characteristics with a combination of large number of
routing switches in the FastCONNECT II switch matrix, a
54-wide input Function Block, and flexible, bi-directional
product term allocation within each macrocell. These features address design changes that require adding or changing internal routing, including additional signals into existing
equations, or increasing equation complexity, respectively.
For extensive design changes requiring higher logic capacity than is available in the initially chosen device, the new
design may be able to fit into a larger pin-compatible device
using the same pin assignments. The same board may be
used with a higher density device without the expense of
board rework.
In-System Programming
One or more XC9500XV devices can be daisy chained
together and programmed in-system via a standard 4-pin
JTAG protocol, as shown in Figure 15. In-system programming offers quick and efficient design iterations and eliminates package handling. The Xilinx development system
provides the programming data sequence using a Xilinx
download cable, a third-party JTAG development system,
JTAG-compatible board tester, or a simple microprocessor
interface that emulates the JTAG instruction sequence.
All I/Os are set to a high-impedance state and pulled High
by the bus-hold circuitry during in-system programming. If a
particular signal must remain Low during this time, then a
pull-down resistor may be added to the pin.
Reliability and Endurance
All XC9500XV CPLDs provide a minimum endurance level
of 10,000 in-system program/erase cycles and a minimum
data retention of 20 years. Each device meets all functional,
performance, and data retention specifications within this
endurance limit.
IEEE 1149.1 Boundary-Scan (JTAG)
XC9500XV devices fully support IEEE 1149.1 boundary-scan (JTAG). EXTEST, SAMPLE/PRELOAD, BYPASS,
USERCODE, INTEST, IDCODE, HIGHZ and CLAMP
instructions are supported in each device. Additional
instructions are included for in-system programming operations.
V CC
GND
(a)
(b)
X5902
Figure 15: In-System Programming Operation (a) Solder Device to PCB and (b) Program Using Download Cable
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Design Security
Low Power Mode
XC9500XV devices incorporate advanced data security features which fully protect the programming data against
unauthorized reading or inadvertent device erasure/reprogramming. Table 3 shows the four different security settings
available.
All XC9500XV devices offer a low-power mode for individual
macrocells or across all macrocells. This feature allows the
device power to be significantly reduced.
The read security bits can be set by the user to prevent the
internal programming pattern from being read or copied.
When set, they also inhibit further program operations but
allow device erase. Erasing the entire device is the only way
to reset the read security bit.
The write security bits provide added protection against
accidental device erasure or reprogramming when the
JTAG pins are subject to noise, such as during system
power-up. Once set, the write-protection may be deactivated when the device needs to be reprogrammed with a
valid pattern with a specific sequence of JTAG instructions
Table 3: Data Security Options
Write Security
Read Security
Default
Set
Default
Set
Read Allowed
Read Inhibited
Program/Erase
Allowed
Program/Erase
Inhibited
Read Allowed
Read Inhibited
Program/Erase
Allowed
Program/Erase
Inhibited
Each individual macrocell may be programmed in
low-power mode by the user. Performance-critical parts of
the application can remain in standard power mode, while
other parts of the application may be programmed for
low-power operation to reduce the overall power dissipation.
Macrocells programmed for low-power mode incur additional delay (TLP) in pin-to-pin combinatorial delay as well as
register setup time. Product term clock to output and product term output enable delays are unaffected by the macrocell power-setting.
Timing Model
The uniformity of the XC9500XV architecture allows a simplified timing model for the entire device. The basic timing
model, shown in Figure 16, is valid for macrocell functions
that use the direct product terms only, with standard power
setting, and standard slew rate setting. Table 4 shows how
each of the key timing parameters is affected by the product
term allocator (if needed), low-power setting, and slew-limited setting.
The product term allocation time depends on the logic span
of the macrocell function, which is defined as one less than
the maximum number of allocators in the product term path.
If only direct product terms are used, then the logic span is
"0". The example in Figure 6 shows that up to 15 product
terms are available with a span of "1". In the case of
Figure 7, the 18 product term function has a span of "2".
Detailed timing information may be derived from the full timing model shown in Figure 17. The values and explanations
for each parameter are given in the individual device data
sheets.
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Combinatorial
Logic
Combinatorial
Logic
D/T Q
TCO
Clock to Out Time = TCO
Setup Time = TSU
(b)
Propagation Delay = TPD
(a)
TPSU
Combinatorial
Logic
D/T Q
Combinatorial
Logic
P-Term Clock
Path
D/T Q
TPCO
Setup Time = TPSU
Clock to Out Time = TPCO
(c)
Internal System Cycle Time = TSYSTEM
(d)
DS049_16_061200
Figure 16: Basic Timing Model
Table 4: Timing Model Parameters
Product Term
Macrocell
Parameter
Allocator(1)
Low-Power Setting
Output
Slew-Limited
Setting
Propagation Delay
TPD
+ TPTA * S
+ TLP
+ TSLEW
Global Clock Setup Time
TSU
+ TPTA * S
+ TLP
-
Global Clock-to-output
TCO
-
-
+ TSLEW
Product Term Clock Setup
Time
TPSU
+ TPTA * S
+ TLP
-
Product Term
Clock-to-Output
TPCO
-
-
+ TSLEW
TSYSTEM
+ TPTA * S
+ TLP
-
Description
Internal System Cycle
Period
Notes:
1. S = the logic span of the function, as defined in the text.
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TF
TLOGILP
TIN
S*TPTA
TLOGI
TSLEW
TPDI
D/T
Q
TOUT
TSUI TCOI
THI
TPTCK
EC TAOI
TEN
TRAI
TGCK
TPTSR
SR
TGSR
TPTTS
Macrocell
TGTS
DS049_17_061200
Figure 17: Detailed Timing Model
Power-Up Characteristics
The XC9500XV devices are well behaved under all operating conditions. During power-up each XC9500XV device
employs internal circuitry which keeps the device in the quiescent state until the VCCINT supply voltage is at a safe level
(approximately 1.9V). During this time, all device pins and
JTAG pins are disabled and all device outputs are disabled
with the pins weakly pulled High, as shown in Table 5. When
the supply voltage reaches a safe level, all user registers
become initialized (typically within 300 µs), and the device is
immediately available for operation, as shown in Figure 18.
If the device is in the erased state (before any user pattern
is programmed), the device outputs remain disabled with
weak pull-up. The JTAG pins are enabled to allow the device
to be programmed at any time. All devices are shipped in
the erased state from the factory.
JTAG pins are enabled to allow device erasure or boundary-scan tests at any time.
VCCINT
1.9V
3.8
V
(Typ)
(Typ)
0V
If the device is programmed, the device inputs and outputs
take on their configured states for normal operation. The
No
Power
Quiescent
State
User Operation
Quiescent
State
No
Power
Initialization of User Registers
DS049_18_061200
Figure 18: Device Behavior During Power-up
Table 5: XC9500XV Device Characteristics
Device
Quiescent
Erased Device
Valid User
Circuitry
State
Operation
Operation
Pull-up
Pull-up
Bus-Hold
Device Outputs
Disabled
Disabled
As Configured
Device Inputs and Clocks
Disabled
Disabled
As Configured
Function Block
Disabled
Disabled
As Configured
JTAG Controller
Disabled
Enabled
Enabled
IOB Bus-Hold
16
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Advance Product Specification
R
XC9500XV Family High-Performance CPLD
Power-Up Guidelines
Figure 19 shows a block diagram of the internal configuration controller, which transfers the EPROM bits to the
latches. Some important things to note are:
•
The VCCINT is sensed to determine when to begin the
loading.
•
An internal clock source drives a state machine that
controls the overall process.
•
The bit loading process takes about 100 microseconds.
•
Internal configuration latches are automatically reset at
the beginning of the process.
•
bits. It is in this voltage neighborhood the POR circuits begin
transferring EPROM bits to the latches. XC9500XV POR
begins about 1.8V.
Supply arrives at final value
VCC
Configuration completes, part comes "alive"
Strobes
VCCINT
VPOR
+
-
State
Machine
Inactive silicon, slight leakage
0
Time
DS049_20_061200
Figure 20: Power-up Activity
Development System Support
The XC9500XV family and associated in-system programming capabilities are fully supported in either software solutions available from Xilinx.
The Foundation Series is an all-in-one development system
containing schematic entry, HDL (VHDL, Verilog, and
ABEL), and simulation capabilities. It supports the
XC9500XV family as well as other CPLD and FPGA families.
Address
Clock
DS049_19_061200
Figure 19: Configuration Controller
Figure 20 describes what happens inside the chip as the
supply rises to its final value. At low voltage, the transistors
do not behave like transistors. As VCC passes about a volt,
the transistors begin to wake up, but are not yet fully
functional. Above 1V, they can amplify and form basic gates.
Near 1.8V, they work correctly and can make reliable
latches. Above 2V, they can be reliably loaded with EPROM
DS049 (v2.0) January 15, 2001
Advance Product Specification
Logic alive, latches working
Transistors waking up
The state machines, counters and strobes are built
from CMOS transistors, so they need voltage, setup
time, hold time, and propagation delay time to work
properly.
When VCCINT passes a threshold, it automatically enables.
The state machine cycles through addresses, delivers load
strobes to internal latches and completes the process by
enabling the I/O pins.
Reset pulse delivered configuration begins
VPOR
The Alliance Series includes CPLD and FPGA implementation technology as well as all necessary libraries and interfaces for Alliance partner EDA solutions.
The Xilinx WebPOWERED Software Solution offer designers the flexibility to target the XC9500 and CoolRunner®
Series CPLDs on-line with WebFITTER or on the desktop
with WebPACK. WebFITTER is an on-line device fitting and
evaluation tool which accepts HDL, ABEL, or netlist files
and provides all reports, simulation models, and programming files. WebPACK downloadable desktop solutions offer
FREE CPLD software modules for ABEL and HDL synthesis, device fitting and JTAG programming.
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17
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XC9500XV Family High-Performance CPLD
Revision History
The following table shows the revision history for this document..
18
Date
Version
Revision
01/19/99
1.0
Initial Xilinx release. Advance Information Specification.
06/12/00
1.1
Updated 3.3V information, added Output Banking, added DS049 number. Added WebPACK
information and minor edits. Added "Power-Up Guidelines" on page 17.
01/15/01
2.0
New performance and package options, removed references to "Fast Flash".
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DS049 (v2.0) January 15, 2001
Advance Product Specification