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Table of Contents

ADI AD9361 System on Module (SOM) SDR

The ADRV9361-Z7035 is built on a portfolio of highly integrated System-On-Module (SOMs) based on the Xilinx Zynq®-7000 All Programmable (AP)SoC. Starting with the AD9361, it is schematically & HDL similar to the AD-FMCOMMS3-EBZ.

The purpose of the ADRV9361-Z7035 RF SOM is to provide an RF platform to software developers, system architects, product developers, etc, who want a single platform operating over a wide tuning range (70 MHz – 6 GHz) that is capable of being used for prototype, evaluation and production volume.

Table of Contents

  1. Introduction to the AD9361.
  2. Introduction to Boards Based on the AD936x.
    1. Matrix showing which boards work with which carriers.
  3. ADRV9361-Z7035 Hardware
    1. Mechanical Design
    2. Electrical Specifications
    3. Performance
    4. Revision History
  4. Use the ADRV9361-Z7035 SOM Hardware to better understand the AD9361.
    1. Getting started (Think quick start guide)
      1. These should be partitioned more or less according to connector. For example SOM1 and SOM2 have similar QSG, FMCOMMS2345 have similar QSG
    2. Linux Applications
    3. Push custom data into-out of the SOM hardware.
  5. Design with the AD9361
    1. Understanding the AD9361
    2. Simulation
    3. Hardware in the loop – How to design your own custom BaseBand
    4. Targeting
    5. Complete Workflow
    6. Design a custom AD9361 Based Platform
  6. Additional Documentation about SDR Signal Chains
  7. Help and Support
  8. Videos and Webinars
  1. Introduction
  2. RF SOM Hardware
  3. Tuning the system
  4. Environmental Testing
  5. Carriers
    1. FMC Carrier (PZSDRCC-FMC)
    2. Breakout Carrier (PZSDRCC-BRK)
    3. PCIe Carrier (PZSDRCC-PCIE)
    4. PackRF Carrier (PZSDRCC-PackRF)
  6. Power and Sequencing
  7. Use the RF SOM Hardware to better understand the AD9361
    1. What you need to get started
    2. Quick Start Guides
      1. Linux on RF SOM
      2. Configure a pre-existing SD-Card
      3. Update the old card you received with your hardware
    3. Linux Applications
      1. IIO Scope
      2. AD9361 Control IIO Scope Plugin
      3. AD9361 Advanced Control IIO Scope Plugin
      4. Command Line/Shell scripts
    4. Push custom data into/out of the RF SOM SDR.
      1. Basic Data files and formats
      2. Create and analyze data files in MATLAB
      3. Stream data into/out of MATLAB
      4. AD9361 libiio streaming example
  8. Design with the AD9361
    1. Understanding the AD9361
      1. AD9361 Product page
      2. Full Datasheet and chip design package
      3. MATLAB Filter Design Wizard for AD9361
    2. Simulation
      1. MathWorks SimRF Models of the AD9361
    3. Hardware in the Loop / How to design your own custom BaseBand
      1. MATLAB/Simulink Examples
        1. Stream data into/out of MATLAB
        2. Beacon Frame Receiver Example
        3. QPSK Transmit and Receive Example
        4. LTE Transmit and Receive Example
        5. ADS-B Airplane Tracking Example
      2. GNU Radio
      3. FM Radio/Tuner (listen to FM signals on the HDMI monitor)
      4. C example
    4. Targeting
      1. Analog Devices BSP for MathWorks HDL Workflow Advisor
    5. Complete Workflow
      1. ADS-B Airplane Tracking Tutorial
    6. Design a custom AD9361 based platform
      1. Linux software
        1. Linux Device Driver
        2. Build the 2014_R2 Release Linux kernel from source
        3. Customizing the devicetree on the target
      2. No-OS Driver
      3. HDL Reference Design which you must use in your FPGA.
        1. Digital Interface Timing Validation
  9. Additional Documentation about SDR Signal Chains
    1. The math behind the RF
  10. Help and Support
  11. Videos and Webinars
    1. Radio Deployment on SoC Platforms

Warning

All the products described on this page include ESD (electrostatic discharge) sensitive devices. Electrostatic charges as high as 4000V readily accumulate on the human body or test equipment and can discharge without detection.

Although the boards feature ESD protection circuitry, permanent damage may occur on devices subjected to high-energy electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance degradation or loss of functionality. This includes removing static charge on external equipment, cables, or antennas before connecting to the device.

resources/eval/user-guides/adrv9361-z7035.1518627352.txt.gz · Last modified: 14 Feb 2018 17:55 by Neil Wilson

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