XCVU9P-L2FLGB2104E

Product Overview

• Category: Field Programmable Gate Array (FPGA)
• Use: High-performance computing, data center acceleration, machine learning, and artificial intelligence applications
• Characteristics:
  • High logic capacity and processing power
  • Advanced programmability and flexibility
  • Low power consumption
  • High-speed interfaces
• Package: Flip-chip BGA package
• Essence: Xilinx Virtex UltraScale+ FPGA
• Packaging/Quantity: Single unit

Specifications

• Logic Cells: 2,586,720
• DSP Slices: 6,840
• Memory: 34,359 Mb
• Transceivers: 96
• Operating Voltage: 0.85V to 0.95V
• Operating Temperature: -40°C to 100°C
• Package Dimensions: 55mm x 55mm

Detailed Pin Configuration

The XCVU9P-L2FLGB2104E has a complex pin configuration with numerous input/output pins. Please refer to the official datasheet for the complete pinout details.

Functional Features

1. High Performance: The XCVU9P-L2FLGB2104E offers exceptional performance with its large logic capacity, high-speed interfaces, and advanced DSP slices.
2. Flexibility: Being a field-programmable device, it allows users to reconfigure the FPGA according to their specific application requirements.
3. Low Power Consumption: Despite its high performance, the FPGA is designed to operate efficiently with low power consumption, making it suitable for power-sensitive applications.
4. Versatile Interfaces: The FPGA includes a wide range of high-speed transceivers, enabling seamless integration with various communication protocols and standards.

Advantages and Disadvantages

Advantages: - High logic capacity and processing power - Advanced programmability and flexibility - Low power consumption - Versatile high-speed interfaces

Disadvantages: - Complex pin configuration may require careful planning and design considerations - Higher cost compared to lower-end FPGAs

Working Principles

The XCVU9P-L2FLGB2104E operates based on the principles of field-programmable gate arrays. It consists of a large number of configurable logic blocks interconnected through programmable routing resources. Users can program the FPGA using hardware description languages (HDLs) or specialized development tools to define the desired functionality and interconnections.

Once programmed, the FPGA executes the specified logic operations, enabling high-performance computing, data acceleration, and other applications.

Detailed Application Field Plans

The XCVU9P-L2FLGB2104E finds extensive use in various fields, including:

1. High-Performance Computing: The FPGA's large logic capacity and processing power make it ideal for demanding computational tasks in scientific research, financial modeling, and simulations.
2. Data Center Acceleration: With its ability to accelerate specific workloads, the FPGA enhances data center performance by offloading computationally intensive tasks from CPUs.
3. Machine Learning and Artificial Intelligence: The FPGA's parallel processing capabilities and flexibility enable efficient implementation of machine learning algorithms and neural networks.
4. Wireless Communication: The FPGA's high-speed transceivers facilitate the development of advanced wireless communication systems, such as 5G base stations and radar systems.

Detailed and Complete Alternative Models

1. XCVU7P-L2FLGB2104E
2. XCVU9P-L2FLGA2104E
3. XCVU11P-L2FLGB2104E
4. XCVU13P-L2FLGB2104E
5. XCVU15P-L2FLGB2104E

These alternative models offer varying logic capacities, performance levels, and package options to cater to different application requirements.

Note: The content provided above is a sample structure for an encyclopedia entry and may not reflect the actual specifications or details of the mentioned product.