EP1SGX10CF672C7

Product Overview

• Category: Field Programmable Gate Array (FPGA)
• Use: Digital logic implementation, prototyping, and system integration
• Characteristics:
  • High-performance programmable logic device
  • Advanced architecture for complex designs
  • Flexible and reconfigurable functionality
  • Integration of various digital functions
• Package: Ceramic Ball Grid Array (BGA)
• Essence: Versatile and customizable integrated circuit
• Packaging/Quantity: Single unit per package

Specifications

• Manufacturer: Intel Corporation
• Model: EP1SGX10CF672C7
• Technology: 65nm
• Logic Elements: 9,600
• Embedded Memory: 1,638,400 bits
• Maximum User I/Os: 672
• Operating Voltage: 1.2V
• Operating Temperature: -40°C to 100°C
• Package Dimensions: 27mm x 27mm

Detailed Pin Configuration

The EP1SGX10CF672C7 FPGA has a total of 672 pins distributed across its package. The pin configuration includes dedicated input/output pins, power supply pins, ground pins, and configuration pins. These pins are arranged in a specific pattern on the BGA package, allowing for easy connection with external components and devices.

For a detailed pin configuration diagram, please refer to the manufacturer's datasheet or documentation.

Functional Features

• High-Speed Processing: The EP1SGX10CF672C7 FPGA offers high-speed processing capabilities, making it suitable for applications requiring real-time data processing and complex computations.
• Reconfigurability: The FPGA can be reprogrammed multiple times, allowing for flexibility in adapting to changing requirements or design iterations.
• Integration: The device integrates various digital functions, such as arithmetic logic units, memory blocks, and input/output interfaces, enabling the implementation of complex systems on a single chip.
• Customizability: With its programmable nature, the FPGA allows users to create custom logic circuits tailored to their specific application needs.

Advantages

• Versatility: The EP1SGX10CF672C7 FPGA can be used in a wide range of applications due to its flexibility and reconfigurability.
• High Performance: The advanced architecture and high-speed processing capabilities enable efficient execution of complex algorithms and tasks.
• Integration Efficiency: By integrating multiple digital functions into a single chip, the FPGA reduces the need for additional components, saving space and simplifying system design.
• Rapid Prototyping: The reprogrammable nature of the FPGA facilitates quick prototyping and iterative development cycles.

Disadvantages

• Complex Design Process: Utilizing the full potential of an FPGA requires expertise in digital design and programming, making it less accessible for beginners or those without specialized knowledge.
• Higher Power Consumption: Compared to dedicated application-specific integrated circuits (ASICs), FPGAs generally consume more power due to their programmable nature and additional circuitry for reconfiguration.

Working Principles

The EP1SGX10CF672C7 FPGA operates based on the principles of configurable logic. It consists of an array of programmable logic elements interconnected through configurable routing resources. These logic elements can be programmed to implement desired digital functions by configuring their internal look-up tables, flip-flops, and interconnections.

Upon configuration, the FPGA executes the programmed logic, performing various operations based on the input signals received. The reconfigurable nature of the FPGA allows for dynamic changes to the implemented logic, enabling adaptability and customization.

Detailed Application Field Plans

The EP1SGX10CF672C7 FPGA finds applications in various fields, including:

1. Communications: Used in wireless base stations, network routers, and communication infrastructure for signal processing, protocol handling, and data transmission.
2. Industrial Automation: Employed in control systems, robotics, and factory automation for real-time monitoring, process control, and sensor interfacing.
3. Medical Devices: Utilized in medical imaging equipment, patient monitoring systems, and diagnostic devices for data processing, image reconstruction, and signal analysis.
4. Aerospace and Defense: Integrated into avionics systems, radar systems, and military equipment for high-speed data processing, encryption, and signal intelligence.
5. Automotive: Applied in advanced driver-assistance systems (ADAS), infotainment systems, and engine control units (ECUs) for sensor fusion, image recognition, and vehicle diagnostics.

Detailed and Complete Alternative Models

1. Altera Cyclone IV EP4CE115F29C7N
2. Xilinx Spartan-6 XC6SLX9-2CSG324C
3. Lattice iCE40UP5K-SG48I 4