XC7V2000T-2FHG1761C

Product Overview

Category

The XC7V2000T-2FHG1761C belongs to the category of Field-Programmable Gate Arrays (FPGAs).

Use

FPGAs are integrated circuits that can be programmed and reprogrammed to perform various digital functions. The XC7V2000T-2FHG1761C is specifically designed for high-performance applications that require complex logic functions.

Characteristics

• High capacity: The XC7V2000T-2FHG1761C offers a large number of programmable logic cells, making it suitable for handling complex designs.
• High-speed performance: With advanced architecture and optimized routing, this FPGA can operate at high clock frequencies, enabling rapid data processing.
• Flexible configuration: The device can be easily reprogrammed to adapt to changing requirements, allowing for quick prototyping and design iterations.
• Low power consumption: The XC7V2000T-2FHG1761C incorporates power-saving features, making it energy-efficient for battery-powered applications.
• Robust packaging: The FPGA is packaged in a 1761-pin Fine-Pitch Ball Grid Array (FBGA), ensuring reliable electrical connections and mechanical stability.

Packaging/Quantity

The XC7V2000T-2FHG1761C is available in a single package. Each package contains one unit of the FPGA.

Specifications

• Device family: Virtex-7
• Logic cells: 2,000,000
• Block RAM: 4,860 Kb
• DSP slices: 3,600
• Maximum operating frequency: 800 MHz
• I/O standards: LVCMOS, LVTTL, HSTL, SSTL, LVDS, etc.
• Operating voltage: 1.0V
• Package type: FBGA
• Package pins: 1761

Detailed Pin Configuration

The XC7V2000T-2FHG1761C has a complex pin configuration with 1761 pins. For detailed information on the pin assignments and functions, please refer to the manufacturer's datasheet.

Functional Features

• Programmable logic cells: The FPGA provides a large number of configurable logic cells that can be interconnected to implement various digital functions.
• Block RAM: The device includes dedicated memory blocks for efficient storage and retrieval of data.
• DSP slices: Integrated Digital Signal Processing (DSP) slices enable high-performance signal processing capabilities.
• Clock management: The FPGA offers flexible clocking options, including phase-locked loops (PLLs) for precise timing control.
• High-speed I/O: The device supports various high-speed I/O standards, allowing for seamless integration with external devices.

Advantages and Disadvantages

Advantages

• Versatility: The XC7V2000T-2FHG1761C can be programmed to perform a wide range of functions, making it suitable for diverse applications.
• High performance: With its large capacity and optimized architecture, the FPGA delivers excellent performance in terms of speed and throughput.
• Flexibility: The ability to reprogram the device allows for quick design iterations and adaptability to changing requirements.
• Power efficiency: The FPGA incorporates power-saving features, making it suitable for energy-conscious applications.

Disadvantages

• Complexity: The extensive configurability of FPGAs can make the design process more challenging and time-consuming compared to using fixed-function integrated circuits.
• Cost: FPGAs tend to be more expensive than traditional microcontrollers or application-specific integrated circuits (ASICs).
• Learning curve: Working with FPGAs requires specialized knowledge and expertise in hardware description languages and digital design.

Working Principles

FPGAs are based on a matrix of configurable logic cells interconnected through programmable routing resources. The XC7V2000T-2FHG1761C utilizes a combination of look-up tables, flip-flops, and other components to implement complex digital functions. These functions are defined by the user through hardware description languages (HDLs) such as VHDL or Verilog. Once programmed, the FPGA can execute the desired logic operations.

Detailed Application Field Plans

The XC7V2000T-2FHG1761C finds applications in various fields, including:

1. Communications: The FPGA can be used for high-speed data processing, protocol conversion, and signal modulation/demodulation in communication systems.
2. Aerospace and Defense: Its high-performance capabilities make it suitable for radar systems, avionics, and secure communications.
3. Industrial Automation: FPGAs can be employed in control systems, robotics, and machine vision applications for real-time processing and precise control.
4. Medical Devices: The device can be utilized in medical imaging, patient monitoring, and diagnostic equipment for fast and accurate data processing.
5. Research and Development: FPGAs are widely