DS013 (v2.7) March 31, 2006
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Features
• Low power 3.3V 256 macrocell CPLD
• 7.0 ns pin-to-pin logic delays
• System frequencies up to 154 MHz
• 256 macrocells with 6,000 usable gates
• Available in small footprint packages
- 144-pin TQFP (120 user I/O pins)
- 208-pin PQFP (164 user I/O)
- 256-ball FBGA (164 user I/O)
- 280-ball CS BGA (164 user I/O)
• Optimized for 3.3V systems
- Ultra low power operation
- Typical Standby Current of 18 μA at 25°
C
- 5V tolerant I/O pins with 3.3V core supply
- Advanced 0.35 micron five layer metal EEPROM
process
- Fast Zero Power™ (FZP) CMOS design
technology
- 3.3V PCI electrical specification compatible outputs
(no internal clamp diode on any input or I/O)
• Advanced system features
- In-system programming
- Input registers
- Predictable timing model
- Up to 23 clocks available per function block
- Excellent pin retention during design changes
- Full IEEE Standard 1149.1 boundary-scan (JTAG)
- Four global clocks
- Eight product term control terms per function block
• Fast ISP programming times
• Port Enable pin for additional I/O
• 2.7V to 3.6V supply voltage at industrial grade voltage
range
• Programmable slew rate control per output
• Security bit prevents unauthorized access
• Refer to the CoolRunner™ XPLA3 family data sheet
(DS012
) for architecture description
Description
The CoolRunner™ XPLA3 XCR3256XL device is a 3.3V,
256 macrocell CPLD targeted at power sensitive designs
that require leading edge programmable logic solutions. A
total of 16 function blocks provide 6,000 usable gates.
Pin-to-pin propagation delays are as fast as 7.0 ns with a
maximum system frequency of 154 MHz.
TotalCMOS Design Technique for Fast
Zero Power
CoolRunner XPLA3 CPLDs offer a TotalCMOS™ solution,
both in process technology and design technique. These
CPLDs employ a cascade of CMOS gates to implement
their sum of products, instead of the traditional sense amp
approach. This CMOS gate implementation allows Xilinx
CPLDs to offer devices that are both high performance and
low power, breaking the paradigm that to have low power,
you must have low performance. Refer to Figure 1 and
Table 1 showing the I
CC
vs. Frequency of our XCR3256XL
TotalCMOS CPLD (data taken with 16 resetable up/down,
16-bit counters at 3.3V, 25°C).
0
XCR3256XL 256 Macrocell CPLD
DS013 (v2.7) March 31, 2006
014
Product Specification
R
Figure 1: Typical I
CC
vs. Frequency at V
CC
= 3.3V, 25°C
Frequency (MHz)
CC
0
0
20
40
60
80
120
100
120 140 16
10080604020
XCR3256XL
Table 1: Typical I
CC
vs. Frequency at V
CC
= 3.3V, 25°C
Frequency (MHz)0 1 1020406080100120140
Typical I
CC
(mA) 0.018 0.98 9.69 19.3 38.1 56.2 73.7 90.8 107.3 123.9