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Embedded - FPGAs (Field Programmable Gate Array)

Image Part Number Description / PDF Quantity Rfq
XA7S25-2CSGA225I

XA7S25-2CSGA225I

Xilinx

IC FPGA 150 I/O 225CSBGA

0
XC5VLX330-2FFG1760C

XC5VLX330-2FFG1760C

Xilinx

IC FPGA 1200 I/O 1760FCBGA

0
XC5VLX85T-1FF1136C

XC5VLX85T-1FF1136C

Xilinx

IC FPGA 480 I/O 1136FCBGA

0
XC7A35T-3CSG324E

XC7A35T-3CSG324E

Xilinx

IC FPGA 210 I/O 324CSBGA

0
XC5VSX50T-3FFG665C

XC5VSX50T-3FFG665C

Xilinx

IC FPGA 360 I/O 665FCBGA

0
XC3S50-5VQG100C

XC3S50-5VQG100C

Xilinx

IC FPGA 63 I/O 100VQFP

0
XC7K160T-2FB676I

XC7K160T-2FB676I

Xilinx

IC FPGA 400 I/O 676FCBGA

0
XC4VFX100-11FFG1152I

XC4VFX100-11FFG1152I

Xilinx

IC FPGA 576 I/O 1152FCBGA

0
XC4005XL-09VQ100C

XC4005XL-09VQ100C

Xilinx

FPGA, 196 CLBS, 3000 GATES, 217M

27
XC4VLX100-11FFG1148C

XC4VLX100-11FFG1148C

Xilinx

IC FPGA 768 I/O 1148FCBGA

0
XCKU5P-L2FFVB676E

XCKU5P-L2FFVB676E

Xilinx

IC FPGA 280 I/O 676FCBGA

0
XC6SLX100T-2FG900I

XC6SLX100T-2FG900I

Xilinx

IC FPGA 498 I/O 900FBGA

0
XC2S150-5FGG456C

XC2S150-5FGG456C

Xilinx

IC FPGA 260 I/O 456FBGA

111
XC3S250E-5FTG256C

XC3S250E-5FTG256C

Xilinx

IC FPGA 172 I/O 256FTBGA

0
XC3S200-4FT256C

XC3S200-4FT256C

Xilinx

IC FPGA 173 I/O 256FTBGA

0
XC6SLX16-2FT256I

XC6SLX16-2FT256I

Xilinx

IC FPGA 186 I/O 256FTBGA

0
XC7VX415T-2FFG1927I

XC7VX415T-2FFG1927I

Xilinx

IC FPGA 600 I/O 1927FCBGA

0
XC6SLX9-3CPG196C

XC6SLX9-3CPG196C

Xilinx

IC FPGA 106 I/O 196CSBGA

0
XC7K410T-2FBV676I

XC7K410T-2FBV676I

Xilinx

IC FPGA 400 I/O 676FCBGA

0
XCKU040-3FFVA1156E

XCKU040-3FFVA1156E

Xilinx

IC FPGA 520 I/O 1156FCBGA

0

Embedded - FPGAs (Field Programmable Gate Array)

1. Overview

Field Programmable Gate Arrays (FPGAs) are reconfigurable semiconductor devices containing programmable logic blocks and interconnects. They enable hardware-level customization for specific computational tasks, offering flexibility unmatched by ASICs or microprocessors. In modern technology, FPGAs are critical for applications requiring parallel processing, low-latency execution, and real-time adaptability, such as AI acceleration, 5G communications, and industrial automation.

2. Main Types and Functional Classification

TypeFunctional FeaturesApplication Examples
Low-Cost FPGAsOptimized for budget-sensitive applications with minimal logic densityConsumer electronics, IoT edge devices
High-Performance FPGAsAdvanced DSP blocks, high-speed transceivers (>100 Gbps)Data centers, radar systems
SoC FPGAsIntegrated ARM processors with FPGA fabricIndustrial control, medical imaging
MPSoC FPGAsMulti-core processors with AI acceleration enginesAutonomous vehicles, 5G base stations

3. Architecture and Components

A typical FPGA consists of:

  • Logic Units: Configurable Lookup Tables (LUTs) and flip-flops for implementing Boolean functions
  • Routing Resources: Programmable interconnects for signal pathways
  • I/O Interfaces: Standardized protocols (PCIe, DDR4, Ethernet)
  • Embedded Memory: Block RAM and distributed RAM for data storage
  • Clock Management: Phase-Locked Loops (PLLs) for precise timing control
  • DSP Blocks: Hardened multipliers and accumulators for signal processing

4. Key Technical Specifications

ParameterDescriptionImportance
Logic CellsNumber of configurable logic units (10K 2M+)Determines computational complexity
Max FrequencyOperating speed (100 MHz 1 GHz)Impacts processing throughput
Power ConsumptionThermal Design Power (TDP: 1W 100W)Critical for battery-powered systems
Package TypeBGA, Flip-Chip, System-in-Package (SiP)Affects PCB integration
Memory BandwidthData transfer rate (10 GB/s 1 TB/s)Essential for AI/data-intensive tasks

5. Application Domains

  • Telecommunications: 5G NR base stations, optical network switches
  • Industrial: Motor control, machine vision systems
  • Automotive: ADAS sensor fusion, LiDAR processing
  • Healthcare: MRI image reconstruction, ultrasound beamforming
  • Aerospace: Satellite communication modems, flight control systems

6. Leading Manufacturers and Products

VendorRepresentative ProductKey Features
XilinxZynq UltraScale+ MPSoCQuad-core ARM Cortex-A53 + 1.6M logic cells
IntelStratix 10 GX10M logic elements, 14 Gbps transceivers
LatticeMachXO3DLow-power <100K LUTs with security features
MicrochipPolarFire SoC256-bit RISC-V processor, 4.9M logic cells

7. Selection Guidelines

Key considerations:

  • Evaluate required logic density and I/O bandwidth
  • Balance performance vs. power budget (e.g., automotive vs. data center)
  • Assess toolchain support (Vivado, Quartus, etc.)
  • Consider long-term availability for industrial/medical systems
  • Verify protocol compatibility (e.g., PCIe Gen5, DDR5)

8. Industry Trends

Future directions include:

  • AI-optimized FPGAs with integrated tensor cores
  • 3D-stacked memory integration for >1 TB/s bandwidth
  • Open-source toolchain adoption (e.g., GHDL, Yosys)
  • Heterogeneous computing with hybrid CPU-GPU-FPGA architectures
  • Advanced node processes (5nm/3nm) enabling 10M+ logic cells
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