High-Precision Dead-Time Intellectual Property Core and Its Compensation for Inverters

Q3 Multidisciplinary

Wuhan University Journal of Natural Sciences Pub Date : 2023-06-01 DOI:10.1051/wujns/2023283271

Hao-Wen Chen, Sanjun Liu, Guohong Lai

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引用次数: 0

Abstract

In the inverter circuit, there exists a specific on-off time in each power transistor. As such, to prevent a short circuit of the two switch devices on the upper and lower bridge arms, a specific dead time must be set in the pulse width modulation (PWM) and the sinusoidal pulse width modulation (SPWM) signals. In this paper, an intellectual property (IP) core that can introduce a high-precision dead time of arbitrary length into PWM or SPWM signals of the inverter is designed to increase the precision, convenience and generalization of dead time control, resulting in a boosted control accuracy of up to 10 ns. Moreover, the added Avalon bus enables IP cores to be accessed by the field programmable gate array (FPGA) processor in a standard manner and multiple IP cores of the same class can be easily incorporated. In addition, an application for setting and compensating for dead time in a three-phase inverter based on system on programmable chip (SOPC) technology is presented. With the Nios II CPU as its core, the system adopts the mean voltage compensation method to calculate the compensation voltage, and performs dead-time compensation in a feed-forward manner. The three dead-time IP cores are controlled by Avalon bus. These allow the dead time of three groups of power transistors to be accurately controlled and flexibly adjusted. The system also features the master computer communication function while boasting the advantages of flexible control, high precision and low cost.

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高精度死区知识产权核心及其逆变器补偿

在逆变电路中，每个功率晶体管都有一个特定的通断时间。因此，为了防止上下桥臂上的两个开关器件短路，必须在脉宽调制(PWM)和正弦脉宽调制(SPWM)信号中设置特定的死区时间。为了提高死区时间控制的精度、便利性和通用性，本文设计了一种可以在逆变器的PWM或SPWM信号中引入任意长度的高精度死区时间的知识产权(IP)内核，从而将控制精度提高到10ns。此外，增加的Avalon总线使IP核能够通过现场可编程门阵列(FPGA)处理器以标准方式访问，并且可以轻松合并多个同类IP核。此外，还介绍了基于可编程芯片系统(SOPC)技术在三相逆变器死区时间设定与补偿中的应用。系统以Nios II CPU为核心，采用平均电压补偿法计算补偿电压，并采用前馈方式进行死区补偿。三个死区IP核由Avalon总线控制。这使得三组功率晶体管的死区时间可以精确控制和灵活调整。该系统具有主控机通信功能，同时具有控制灵活、精度高、成本低等优点。

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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来源期刊

Wuhan University Journal of Natural Sciences Multidisciplinary-Multidisciplinary

CiteScore

0.40

自引率

0.00%

发文量

2485

期刊介绍： Wuhan University Journal of Natural Sciences aims to promote rapid communication and exchange between the World and Wuhan University, as well as other Chinese universities and academic institutions. It mainly reflects the latest advances being made in many disciplines of scientific research in Chinese universities and academic institutions. The journal also publishes papers presented at conferences in China and abroad. The multi-disciplinary nature of Wuhan University Journal of Natural Sciences is apparent in the wide range of articles from leading Chinese scholars. This journal also aims to introduce Chinese academic achievements to the world community, by demonstrating the significance of Chinese scientific investigations.