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| resources:eval:user-guides:picozed_sdr:tutorials:adsb [09 Jan 2021 00:39] – user interwiki links Robin Getz | resources:eval:user-guides:picozed_sdr:tutorials:adsb [14 Feb 2021 05:29] – fix links Robin Getz |
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| Hardware-Software Co-Design is a standard workflow provided by [[mw>help/supportpkg/xilinxzynqbasedradio/index.html|MathWorks Communications System Toolbox Support Package for Xilinx Zynq-Based Radio]]. Using this workflow, you can prototype an algorithm in Simulink and then deploy it on the ARM processor and FPGA fabric of the Zynq hardware. | Hardware-Software Co-Design is a standard workflow provided by [[mw>help/supportpkg/xilinxzynqbasedradio/index.html|MathWorks Communications System Toolbox Support Package for Xilinx Zynq-Based Radio]]. Using this workflow, you can prototype an algorithm in Simulink and then deploy it on the ARM processor and FPGA fabric of the Zynq hardware. |
| The hardware-software co-design workflow includes FPGA targeting, HDL IP core generation, and the generation of a software interface model for execution on the ARM processor. To get started, see [[mw>help/supportpkg/xilinxzynqbasedradio/ug/hardware-software-co-design-with-communications-system-toolbox-support-package-for-xilinx-zynq-based-radio.html|Hardware-Software Co-Design for Zynq SDR Applications]]. | The hardware-software co-design workflow includes FPGA targeting, HDL IP core generation, and the generation of a software interface model for execution on the ARM processor. To get started, see [[mw>help/supportpkg/xilinxzynqbasedradio/ug/installation-for-hardware-software-co-design.html|Hardware-Software Co-Design for Zynq SDR Applications]]. |
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| The [[mw>help/supportpkg/xilinxzynqbasedradio/examples/hw-sw-co-design-implementation-of-ads-b-transmitter-receiver-using-analog-devices-ad9361-ad9364.html|HW/SW Co-Design Implementation of ADS-B Transmitter/Receiver Using Analog Devices AD9361/AD9364]] is a shipped example in MATLAB from **//R2016b//**. In this example, the stateflow block is removed and replaced with a MATLAB state machine, which means users without a stateflow license can use the model. | The [[mw>help/supportpkg/xilinxzynqbasedradio/examples/hw-sw-co-design-implementation-of-ads-b-transmitter-receiver-using-analog-devices-ad9361-ad9364.html|HW/SW Co-Design Implementation of ADS-B Transmitter/Receiver Using Analog Devices AD9361/AD9364]] is a shipped example in MATLAB from **//R2016b//**. In this example, the stateflow block is removed and replaced with a MATLAB state machine, which means users without a stateflow license can use the model. |
| === Use External Mode === | === Use External Mode === |
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| With [[mw>help/supportpkg/xilinxzynq7000ec/ug/external-mode.html|external mode]], you can log signals and tune parameters while the model is running on the target hardware in real-time. When you change parameter values from within Simulink, the modified parameter values are communicated to the target hardware immediately. | With [[mw>help/supportpkg/xilinxzynq7000ec/ug/parameter-tuning-with-external-mode-simulation.html|external mode]], you can log signals and tune parameters while the model is running on the target hardware in real-time. When you change parameter values from within Simulink, the modified parameter values are communicated to the target hardware immediately. |
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| The Analog Devices BSP also allows external mode for the supported Analog Devices boards. This enables the Simulink models used for IP core generation to be run in external mode and talk to the target hardware running the Analog Devices Linux distribution. | The Analog Devices BSP also allows external mode for the supported Analog Devices boards. This enables the Simulink models used for IP core generation to be run in external mode and talk to the target hardware running the Analog Devices Linux distribution. |
