Code development of a DSP-FPGA based control platform for power electronics applications

2015 IEEE International Conference on Industrial Technology (ICIT) Pub Date : 2015-03-17 DOI:10.1109/ICIT.2015.7125524

V. Miñambres-Marcos, I. Roasto, P. Szczepankowski, E. Romero-Cadaval, D. Vinnikov, F. Barrero-González

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引用次数: 1

Abstract

This paper focuses on the implementation of power electronics algorithms in control platforms based on DSP-FPGA. Today's power electronics technology demands high power computation with high speed interfacing at the same time. The most popular configuration is a DSP for the former and a FPGA for the latter. The main goal of this work was to develop a generic control system for power electronics application, but it is explained for an active power electronic transformer, which will be an active player in the energy storage, management and production game in the smart grids. Thus, demands for the control system are high, so it is mandatory to have a reliable, fast and user friendly control algorithm basis. The control board (SH363) used in this work contains a SHARC ADSP21363 DSP and a CYCLONE II EP2C8F256I8N FPGA. FPGA as a system interface, critical and non-critical communications between DSP and FPGA, including synchronization, and DSP programming are detailed. Also, a PC interface has been developed for an easy debugging and future system management. The methods used to achieve the maximum loop control frequency and the issues found during the implementation are discussed. The performance of the control board of the active power electronic transformer is verified experimentally.

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基于DSP-FPGA的电力电子应用控制平台的代码开发

本文主要研究了基于DSP-FPGA的电力电子算法在控制平台上的实现。当今的电力电子技术要求在高速接口的同时实现高功率计算。最流行的配置是DSP用于前者，FPGA用于后者。本工作的主要目标是开发一种通用的电力电子应用控制系统，但它解释了一种有源电力电子变压器，它将在智能电网的储能、管理和生产游戏中发挥积极作用。因此，对控制系统的要求很高，因此必须有一个可靠、快速和用户友好的控制算法基础。本文使用的控制板(SH363)包含一个SHARC ADSP21363 DSP和一个CYCLONE II EP2C8F256I8N FPGA。详细介绍了FPGA作为系统接口，DSP与FPGA之间的关键和非关键通信，包括同步和DSP编程。同时，为了便于调试和以后的系统管理，还开发了PC机接口。讨论了实现最大回路控制频率的方法和实现过程中遇到的问题。对有源电力电子变压器控制板的性能进行了实验验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2015 IEEE International Conference on Industrial Technology (ICIT)

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