XCV50E-8CS144C

Product Overview

Category

XCV50E-8CS144C belongs to the category of Field Programmable Gate Arrays (FPGAs).

Use

This product is primarily used in digital circuit design and implementation. FPGAs provide a flexible platform for designing and prototyping complex digital systems.

Characteristics

• High flexibility: FPGAs can be reprogrammed multiple times, allowing for iterative design and testing.
• Parallel processing: FPGAs can perform multiple operations simultaneously, making them suitable for high-performance computing applications.
• Customizability: Users can configure the FPGA to meet their specific requirements by programming the logic gates and interconnections.

Package

The XCV50E-8CS144C comes in a 144-pin chip-scale package (CSP). This compact packaging allows for efficient integration into electronic devices.

Essence

The essence of XCV50E-8CS144C lies in its ability to provide a programmable hardware platform that enables the implementation of complex digital circuits.

Packaging/Quantity

The XCV50E-8CS144C is typically sold individually or in small quantities, depending on the manufacturer's packaging specifications.

Specifications

• Logic Cells: 50,000
• Flip-Flops: 100,000
• Block RAM: 1,152 Kbits
• DSP Slices: 192
• Maximum Frequency: 400 MHz
• I/O Pins: 144
• Operating Voltage: 1.2V

Detailed Pin Configuration

The pin configuration of XCV50E-8CS144C is as follows:

| Pin Number | Pin Name | Description | |------------|----------|-------------| | 1 | VCCINT | Power supply voltage for internal circuitry | | 2 | GND | Ground reference | | 3 | IOB0 | Input/output buffer pin 0 | | ... | ... | ... | | 144 | IOB143 | Input/output buffer pin 143 |

Functional Features

• High-speed performance: The XCV50E-8CS144C offers fast processing capabilities, making it suitable for applications requiring real-time data processing.
• Embedded memory: The built-in block RAM allows for efficient storage and retrieval of data within the FPGA.
• Configurable I/O standards: The device supports various I/O standards, enabling compatibility with different communication protocols.
• Clock management: The FPGA includes clock management resources, such as phase-locked loops (PLLs), to facilitate precise timing control.

Advantages and Disadvantages

Advantages

• Flexibility: FPGAs can be reprogrammed, allowing for design modifications without the need for hardware changes.
• High-performance computing: FPGAs excel in parallel processing tasks, making them suitable for computationally intensive applications.
• Prototyping and testing: FPGAs enable rapid prototyping and testing of digital circuits, reducing development time.

Disadvantages

• Complexity: Designing for FPGAs requires specialized knowledge and expertise in digital circuit design.
• Power consumption: FPGAs can consume more power compared to application-specific integrated circuits (ASICs) for similar functionalities.
• Cost: FPGAs tend to be more expensive than other programmable logic devices due to their advanced features and capabilities.

Working Principles

FPGAs consist of an array of configurable logic blocks (CLBs) interconnected through programmable routing resources. The CLBs contain look-up tables (LUTs) that can implement any Boolean function, flip-flops for storing state information, and multiplexers for routing signals. By programming the interconnections and configuring the LUTs, users can define the desired functionality of the FPGA.

Detailed Application Field Plans

The XCV50E-8CS144C finds applications in various fields, including:

1. Communications: FPGAs are used in wireless base stations, network routers, and communication protocols to enable high-speed data processing and signal modulation/demodulation.
2. Image and video processing: FPGAs can accelerate image and video processing tasks, such as real-time video encoding/decoding, object recognition, and computer vision algorithms.
3. Industrial automation: FPGAs play a crucial role in industrial control systems, robotics, and machine vision applications, providing real-time control and high-speed data processing capabilities.
4. Aerospace and defense: FPGAs are utilized in radar systems, avionics, satellite communication, and encryption/decryption applications due to their reliability, reconfigurability, and high-performance computing capabilities.

Detailed and Complete Alternative Models

1. XCV1000E-6FG680C: This FPGA offers higher logic capacity and more I/O pins compared to XCV50E-8CS144C, making it suitable for larger-scale designs.
2. XCV300