LFE2-6E-5FN256C

Product Overview

Category

The LFE2-6E-5FN256C 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 LFE2-6E-5FN256C is specifically designed for applications requiring high-performance and low-power consumption.

Characteristics

• High performance: The LFE2-6E-5FN256C offers a combination of high logic density and fast performance, making it suitable for demanding applications.
• Low power consumption: This FPGA is designed to minimize power consumption, making it energy-efficient.
• Versatility: The LFE2-6E-5FN256C can be customized and reprogrammed to meet specific application requirements.
• Compact package: It comes in a 256-pin FineLine BGA package, which provides a small form factor for space-constrained designs.
• Packaging/Quantity: The LFE2-6E-5FN256C is typically available in tape and reel packaging, with a quantity of one unit per reel.

Specifications

• Logic elements: 6,000
• Number of I/O pins: 256
• Operating voltage: 1.2V
• Maximum operating frequency: 400MHz
• Embedded memory: 288 Kbits
• Configuration memory: 4 Mbits
• Package dimensions: 17mm x 17mm

Detailed Pin Configuration

The LFE2-6E-5FN256C has 256 I/O pins, each serving a specific function within the FPGA's architecture. A detailed pin configuration diagram can be found in the product datasheet.

Functional Features

• High-speed data processing: The LFE2-6E-5FN256C can handle complex data processing tasks at high speeds, making it suitable for applications such as signal processing and image/video processing.
• Flexible I/O capabilities: The FPGA offers a wide range of I/O options, allowing for seamless integration with external devices and systems.
• On-chip memory: The embedded memory within the LFE2-6E-5FN256C enables efficient storage and retrieval of data during operation.
• Configurability: The FPGA's programmable nature allows for customization and adaptation to specific application requirements.

Advantages and Disadvantages

Advantages

• High performance and low power consumption make it ideal for power-sensitive applications.
• Versatility and configurability enable flexibility in design and implementation.
• Compact package size allows for space-efficient designs.

Disadvantages

• Limited logic elements compared to higher-end FPGAs, which may restrict the complexity of certain designs.
• Higher cost compared to other non-programmable integrated circuits for simpler applications.

Working Principles

The LFE2-6E-5FN256C operates based on the principles of reconfigurable computing. It consists of an array of configurable logic blocks interconnected through programmable routing resources. These logic blocks can be programmed to implement various digital functions, enabling the FPGA to perform specific tasks as required by the application.

Detailed Application Field Plans

The LFE2-6E-5FN256C finds applications in various fields, including: 1. Communications: Used in wireless communication systems for signal processing and protocol implementation. 2. Industrial automation: Employed in control systems for real-time monitoring and control of industrial processes. 3. Aerospace and defense: Utilized in radar systems, avionics, and secure communication systems. 4. Medical devices: Integrated into medical imaging equipment and diagnostic instruments for data processing and analysis. 5. Automotive electronics: Applied in advanced driver assistance systems (ADAS) and in-vehicle infotainment systems.

Detailed and Complete Alternative Models

1. LFE2-12E-6FN256C: A higher-density FPGA with 12,000 logic elements for more complex designs.
2. LFE2-3E-5FN256C: A lower-density FPGA with 3,000 logic elements suitable for simpler applications.
3. LFE2-20E-5FN256C: A higher-performance FPGA with 20,000 logic elements for demanding applications.

In conclusion, the LFE2-6E-5FN256C is a versatile and high-performance FPGA that offers low power consumption. Its compact package and flexible I/O capabilities make it suitable for various applications in industries such as communications, industrial automation, aerospace, medical devices, and automotive electronics. While it has limitations in terms of logic density, it provides a cost-effective solution for many digital design requirements.