LFE3-17EA-7FTN256C

Product Overview

Category

LFE3-17EA-7FTN256C belongs to the category of Field Programmable Gate Arrays (FPGAs).

Use

This FPGA is commonly used in electronic circuits for various applications such as digital signal processing, data encryption, and high-speed communication.

Characteristics

• High-performance FPGA with advanced programmable logic capabilities.
• Offers a large number of configurable logic blocks (CLBs) and programmable interconnects.
• Provides high-speed I/O interfaces for efficient data transfer.
• Supports complex arithmetic operations and parallel processing.
• Can be reprogrammed multiple times to adapt to different applications.

Package

LFE3-17EA-7FTN256C comes in a compact package designed for easy integration into electronic systems. The package ensures proper heat dissipation and protection against external factors.

Essence

The essence of LFE3-17EA-7FTN256C lies in its ability to provide flexible and customizable solutions for complex digital circuit designs. It enables designers to implement their desired functionality by programming the FPGA according to specific requirements.

Packaging/Quantity

LFE3-17EA-7FTN256C is typically packaged individually and is available in various quantities depending on the manufacturer's specifications.

Specifications

• Logic Elements: 17,000
• Flip-Flops: 34,000
• Block RAM: 1,080 Kbits
• DSP Blocks: 96
• Maximum User I/Os: 256
• Operating Voltage: 1.2V
• Speed Grade: 7

Detailed Pin Configuration

The pin configuration of LFE3-17EA-7FTN256C is as follows:

• Pin 1: VCCIO
• Pin 2: GND
• Pin 3: VCCINT
• Pin 4: GND
• ...
• Pin 256: IO256

Functional Features

• High-speed data processing capabilities.
• Configurable I/O standards for compatibility with various interfaces.
• On-chip memory resources for efficient data storage and retrieval.
• Built-in digital signal processing blocks for complex arithmetic operations.
• Support for advanced debugging and verification features.

Advantages and Disadvantages

Advantages

• Flexibility in design due to reprogrammability.
• High-performance computing capabilities.
• Reduced time-to-market for electronic products.
• Cost-effective solution compared to custom ASIC designs.

Disadvantages

• Higher power consumption compared to dedicated hardware solutions.
• Limited resource availability for extremely large-scale designs.
• Steeper learning curve for designers unfamiliar with FPGA programming.

Working Principles

LFE3-17EA-7FTN256C operates based on the principles of configurable logic. The FPGA consists of a matrix of programmable logic blocks interconnected through programmable routing resources. By configuring the logic blocks and interconnects, designers can create custom digital circuits that perform specific functions.

Detailed Application Field Plans

LFE3-17EA-7FTN256C finds applications in various fields, including:

1. Telecommunications: Used in high-speed communication systems for data packet processing and protocol handling.
2. Aerospace: Employed in satellite communication systems for signal processing and control functions.
3. Industrial Automation: Utilized in control systems for real-time monitoring and process control.
4. Medical Devices: Integrated into medical imaging systems for image processing and analysis.
5. Automotive: Incorporated in advanced driver assistance systems (ADAS) for sensor fusion and decision-making algorithms.

Detailed and Complete Alternative Models

1. LFE3-17EA-6FN484C
2. LFE3-17EA-8FN484C
3. LFE3-17EA-9FN484C
4. LFE3-17EA-10FN484C

These alternative models offer similar functionality and performance but may differ in terms of logic capacity, I/O count, or package size.

In conclusion, LFE3-17EA-7FTN256C is a high-performance FPGA that provides flexibility and customization options for various digital circuit designs. Its advanced features, such as configurable logic blocks and programmable interconnects, make it suitable for a wide range of applications in different industries. While it has advantages like reprogrammability and cost-effectiveness, it also has limitations such as power consumption and resource constraints. Designers can choose from alternative models with varying specifications to meet their specific requirements.