Cyclone® V 5CSXC5 FPGA

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Specifications

I/O Specifications

Package Specifications

Supplemental Information

Ordering and Compliance

Ordering and spec information

Cyclone® V 5CSXC5 FPGA 5CSXFC5D6F31C8N

  • MM# 968253
  • Spec Code SR6X6
  • Ordering Code 5CSXFC5D6F31C8N
  • Stepping A1
  • ECCN 3A991

Cyclone® V 5CSXC5 FPGA 5CSXFC5C6U23C6N

  • MM# 969327
  • Spec Code SR7UG
  • Ordering Code 5CSXFC5C6U23C6N
  • Stepping A1
  • ECCN EAR99

Cyclone® V 5CSXC5 FPGA 5CSXFC5D6F31I7N

  • MM# 969555
  • Spec Code SR805
  • Ordering Code 5CSXFC5D6F31I7N
  • Stepping A1
  • ECCN 3A991

Cyclone® V 5CSXC5 FPGA 5CSXFC5C6U23A7N

  • MM# 965728
  • Spec Code SR4SV
  • Ordering Code 5CSXFC5C6U23A7N
  • Stepping A1
  • ECCN EAR99

Cyclone® V 5CSXC5 FPGA 5CSXFC5C6U23I7N

  • MM# 968393
  • Spec Code SR713
  • Ordering Code 5CSXFC5C6U23I7N
  • Stepping A1
  • ECCN EAR99

Cyclone® V 5CSXC5 FPGA 5CSXFC5D6F31C7N

  • MM# 968252
  • Spec Code SR6X5
  • Ordering Code 5CSXFC5D6F31C7N
  • Stepping A1
  • ECCN 3A991

Cyclone® V 5CSXC5 FPGA 5CSXFC5D6F31C6N

  • MM# 969551
  • Spec Code SR801
  • Ordering Code 5CSXFC5D6F31C6N
  • Stepping A1
  • ECCN 3A991

Cyclone® V 5CSXC5 FPGA 5CSXFC5C6U23C7N

  • MM# 965729
  • Spec Code SR4SW
  • Ordering Code 5CSXFC5C6U23C7N
  • Stepping A1
  • ECCN EAR99

Cyclone® V 5CSXC5 FPGA 5CSXFC5C6U23C8N

  • MM# 969334
  • Spec Code SR7UP
  • Ordering Code 5CSXFC5C6U23C8N
  • Stepping A1
  • ECCN EAR99

Trade compliance information

  • ECCN Varies By Product
  • CCATS NA
  • US HTS 8542390001

PCN/MDDS Information

SR6X6

SR6X5

SR7UP

SR805

SR7UG

SR713

SR801

SR4SW

SR4SV

Drivers and Software

Latest Drivers & Software

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Name

Technical Documentation

Launch Date

The date the product was first introduced.

Lithography

Lithography refers to the semiconductor technology used to manufacture an integrated circuit, and is reported in nanometer (nm), indicative of the size of features built on the semiconductor.

Logic Elements (LE)

Logic elements (LEs) are the smallest units of logic in Intel® FPGA architecture. LEs are compact and provide advanced features with efficient logic usage.

Adaptive Logic Modules (ALM)

The adaptive logic module (ALM) is the logic building block in supported Intel FPGA devices, and is designed to maximize both performance and utilization. Each ALM has several different modes of operation, and can implement a variety of different combinatorial and sequential logical functions.

Adaptive Logic Module (ALM) Registers

ALM registers are those register bits (flip-flops) that are contained inside the ALMs and are used to implement sequential logic.

Fabric and I/O Phase-Locked Loops (PLLs)

Fabric and IO PLLs are used to simplify the design and implementation of the clock networks in the Intel FPGA fabric, and also the clock networks associated with the IO cells in the device.

Maximum Embedded Memory

The total capacity of all the embedded memory blocks in the programmable fabric of the Intel FPGA device.

Digital Signal Processing (DSP) Blocks

The digital signal processing (DSP) block is the mathematical building block in supported Intel FPGA devices and contains high-performance multipliers and accumulators to implement a variety of digital signal processing functions.

Digital Signal Processing (DSP) Format

Depending on the Intel FPGA device family, the DSP block supports different formats such as hard floating point, hard fixed point, multiply and accumulate, and multiply only.

Hard Processor System (HPS)

The hard processor system (HPS) is a complete hard CPU system contained within the Intel FPGA fabric.

Hard Memory Controllers

Hard memory controllers are used to enable high-performance external memory systems attached to the Intel FPGA. A hard memory controller saves power and FPGA resources compared to the equivalent soft memory controller, and supports higher frequency operation.

External Memory Interfaces (EMIF)

The external memory interface protocols supported by the Intel FPGA device.

Maximum User I/O Count

The maximum number of general purpose I/O pins in the Intel FPGA device, in the largest available package.
† Actual count could be lower depending on package.

I/O Standards Support

The general purpose I/O interface standards supported by the Intel FPGA device.

Maximum LVDS Pairs

The maximum number of LVDS pairs that can be configured in the Intel FPGA device, in the largest available package. Refer to device documentation for actual RX and TX LVDS pairs count by package type.

Maximum Non-Return to Zero (NRZ) Transceivers

The maximum number of NRZ transceivers in the Intel FPGA device, in the largest available package.
† Actual count could be lower depending on package.

Maximum Non-Return to Zero (NRZ) Data Rate

The maximum NRZ data rate that is supported by the NRZ transceivers.
† Actual data rate could be lower depending on transceiver speed grade.

Transceiver Protocol Hard IP

Hard intellectual property available in the Intel FPGA device to support the high-speed serial transceivers. Transceiver protocol hard IP saves power and FPGA resources compared to the equivalent soft IP, and simplifies the implementation of the serial protocol.

FPGA Bitstream Security

Depending on the Intel FPGA device family, various security features are available to prevent copying of the customer bitstream, and detect attempts to tamper with the device during operation.

Analog-to-Digital Converter

The analog-to-digital converter is a data-converter resource available in some Intel FPGA device families.

Package Options

Intel FPGA devices are available in different package sizes, with different IO and transceiver counts, to match customer system requirements.