XC7A35T-L2FGG484E

Product Overview

Category

The XC7A35T-L2FGG484E 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 XC7A35T-L2FGG484E is specifically designed for applications requiring high-performance processing, such as telecommunications, automotive, aerospace, and industrial automation.

Characteristics

• High-performance FPGA with advanced features
• Low power consumption
• Flexible and reconfigurable design
• High-speed data processing capabilities
• Support for various communication protocols
• Extensive I/O options for connectivity

Package and Quantity

The XC7A35T-L2FGG484E comes in a FG484 package, which refers to a fine-pitch ball grid array package with 484 pins. It is available in single-unit quantities or bulk orders depending on the customer's requirements.

Specifications

• Logic Cells: 33,280
• Flip-Flops: 66,560
• Block RAM: 1,800 Kbits
• DSP Slices: 90
• Maximum Frequency: 600 MHz
• Operating Voltage: 1.2V
• Operating Temperature Range: -40°C to 100°C

Pin Configuration

The XC7A35T-L2FGG484E has a well-defined pin configuration that enables easy integration into various electronic systems. The detailed pinout diagram can be found in the product datasheet.

Functional Features

1. High-Speed Processing

The XC7A35T-L2FGG484E offers high-speed data processing capabilities, making it suitable for applications that require real-time performance.

2. Reconfigurability

Being an FPGA, the XC7A35T-L2FGG484E can be reprogrammed to adapt to changing requirements, allowing for flexibility and future-proofing of designs.

3. Extensive I/O Options

With a wide range of I/O options, including LVCMOS, LVDS, and differential signaling, the XC7A35T-L2FGG484E provides versatile connectivity for interfacing with other components or systems.

4. Low Power Consumption

The FPGA is designed to operate efficiently with low power consumption, making it suitable for battery-powered devices or energy-conscious applications.

Advantages and Disadvantages

Advantages

• High-performance processing capabilities
• Flexibility and reconfigurability
• Extensive I/O options for connectivity
• Low power consumption

Disadvantages

• Steep learning curve for programming and utilizing FPGAs effectively
• Higher cost compared to traditional fixed-function integrated circuits

Working Principles

The XC7A35T-L2FGG484E operates based on the principles of digital logic design. It consists of configurable logic blocks, interconnects, and memory elements that can be programmed using Hardware Description Languages (HDL) like VHDL or Verilog. The programmed configuration determines the behavior and functionality of the FPGA.

Application Field Plans

The XC7A35T-L2FGG484E finds applications in various fields, including:

1. Telecommunications: Used in base stations, routers, and network switches for high-speed data processing and protocol handling.
2. Automotive: Employed in advanced driver-assistance systems (ADAS), infotainment systems, and engine control units (ECUs) for real-time processing and control.
3. Aerospace: Utilized in satellite communication systems, avionics, and radar systems for their high-performance computing capabilities.
4. Industrial Automation: Integrated into programmable logic controllers (PLCs), robotics, and factory automation systems for flexible and customizable control.

Alternative Models

For those seeking alternatives to the XC7A35T-L2FGG484E, the following models offer similar functionality:

1. XC7A50T-L2FGG484E
2. XC7A100T-L2FGG484E
3. XC7A200T-L2FGG484E

These models provide varying levels of logic capacity, I/O options, and performance to cater to different application requirements.

In conclusion, the XC7A35T-L2FGG484E is a high-performance FPGA with advanced features, offering flexibility, reconfigurability, and extensive I/O options. It finds applications in telecommunications, automotive, aerospace, and industrial automation fields, among others. While it has advantages such as high-speed processing and low power consumption, it also has a learning curve and higher cost compared to traditional integrated circuits.