Manufacturer | Xilinx |
Mounting Type | Surface Mount |
Number of I/O | 45 |
Package / Case | 56-LFBGA, CSPBGA |
Product Status | Active |
Number of Gates | 1500 |
Programmable Type | In System Programmable |
Number of Macrocells | 64 |
Delay Time tpd(1) Max | 6.7 ns |
Operating Temperature | 0°C ~ 70°C (TA) |
Supplier Device Package | 56-CSBGA (6x6) |
Voltage Supply - Internal | 1.7V ~ 1.9V |
Number of Logic Elements/Blocks | 4 |
The XC2C64A-7CP56C of CoolRunner-II 128-macrocell device is designed for both high performance and low power applications. This lends power savings to high-end communication equipment and high speed to battery operated devices. Due to the low power stand-by and dynamic operation, overall system reliability is improved
This XC2C64A-7CP56C device consists of eight Function Blocks inter-connected by a low power Advanced Interconnect Matrix (AIM). The AIM feeds 40 true and complement inputs to each Function Block. The Function Blocks consist of a 40 by 56 P-term PLA and 16 macrocells which contain numerous configuration bits that allow for combinational or registered modes of operation.
Additionally, these registers can be globally reset or preset and configured as a D or T flip-flop or as a D latch. There are also multiple clock signals, both global and local product term types, configured on a per macrocell basis. Output pin configurations include slew rate limit, bus hold, pull-up, open drain and programmable grounds. A Schmitt-trigger input is available on a per input pin basis. In addition to storing macrocell output states, the macrocell registers may be configured as direct input registers to store signals directly from input pins.
Clocking is available on a global or Function Block basis. Three global clocks are available for all Function Blocks as a synchronous clock source. Macrocell registers can be individually configured to power up to the zero or one state. A global set/reset control line is also available to asynchronously set or reset selected registers during operation. Additional local clock, synchronous clock-enable, asynchronous set/reset and output enable signals can be formed using product terms on a per-macrocell or per-Function Block basis.
A DualEDGE flip-flop feature is also available on a per macrocell basis. This feature allows high performance synchronous operation based on lower frequency clocking to help reduce the total power consumption of the XC2C64A-7CP56C device.
By mapping a signal to the DataGATE function, lower power can be achieved due to reduction in signal switching.
Another feature that eases voltage translation is I/O banking. Two I/O banks are available on the CoolRunner-II 128 macrocell device that permit easy interfacing to 3.3V, 2.5V, 1.8V, and 1.5V devices.
The XC2C64A-7CP56C CPLD is I/O compatible with various JEDEC I/O standards (see Table 1). This device is also 1.5V I/O compatible with the use of Schmitt-trigger inputs.
The Xilinx CPLDs series XC2C64A-7CP56C is 64 MACROCELL 1.8V ZERO POWER ISP CPLD, View Substitutes & Alternatives along with datasheets, stock, pricing from Authorized Distributors at bitfoic.com, and you can also search for other FPGAs products.• In-System Programmable PROMs for Configuration of Xilinx FPGAs
• Low-Power Advanced CMOS NOR Flash Process
• Endurance of 20,000 Program/Erase Cycles
• Operation over Full Industrial Temperature Range (–40°C to +85°C)
• IEEE Standard 1149.1/1532 Boundary-Scan (JTAG) Support for Programming, Prototyping, and Testing
• JTAG Command Initiation of Standard FPGA Configuration
Xilinx is a leading provider of programmable logic devices and associated technologies. As a top producer of programmable FPGAs, SoCs, MPSoCs, and 3D ICs, Xilinx has expanded quickly. Software defined and hardware optimized applications are supported by Xilinx, advancing the fields of cloud computing, SDN/NFV, video/vision, industrial IoT, and 5G wireless.
One of Xilinx's key innovations is the development of the Xilinx Vivado Design Suite, a comprehensive software toolchain used for designing and programming their FPGAs and SoCs. This suite provides developers with the necessary tools to create, simulate, and implement their designs on Xilinx devices.
In October 2020, Xilinx was acquired by Advanced Micro Devices (AMD), a major player in the semiconductor industry. This acquisition has enabled AMD to enhance its product portfolio and expand its offerings into the rapidly growing FPGA market.