直流蓄电池源逆变器供电三相感性负载的海岸功能参数优化

Q2 Energy

International Journal of Power Electronics and Drive Systems Pub Date : 2020-12-01 DOI:10.11591/IJPEDS.V11.I4.PP1799-1804

R. G. Omar

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引用次数: 1

摘要

本文对常用的预测精度度量方法进行了评价。采用绝对误差法、平方误差法、百分比误差法和积分误差法来减小模型预测控制中的目标函数。这些方法通常是针对带三相感应电机负载的有限集模型预测电流控制系统控制的直流逆变器进行研究。本文从准确性、复杂性、系统谐波内容、执行时间等方面进行了评价。在这个过程中，一个重要的标准是逆变器的性能，以及参考电流和测量电流之间的匹配。计算结果表明，对于单项目标函数，绝对误差和平方误差的计算结果相似，且绝对误差的执行时间更短，而对于多项目标函数，平方误差的计算结果更好。

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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Coast function parameters optimization for DC battery source inverter feeding three-phase inductive load

The commonly reported measures of the predictive accuracy are evaluated in this paper. Absolute, squared, percentage, and integral errors methods are implemented, to reduce the objective function, which employed in model predictive control. These methods are usually investigated for dc source inverter, which controlled by finite set model predictive current control system, with three phase induction motor load. In this paper, the evaluation includes different aspects, accuracy, complexity, system harmonics content, and execution time. A vital criterion in this process is the performance of the inverter, and the matching between the reference and the measured machine currents. The evaluation shows that for one term objective function, absolute and square errors give similar results with less execution time for the absolute error, but if multi terms objective function the square error is better.

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来源期刊

International Journal of Power Electronics and Drive Systems Energy-Energy Engineering and Power Technology

CiteScore

3.50

自引率

0.00%

发文量

期刊介绍： International Journal of Power Electronics and Drive Systems (IJPEDS) is the official publication of the Institute of Advanced Engineering and Science (IAES). The journal is open to submission from scholars and experts in the wide areas of power electronics and electrical drive systems from the global world. The scope of the journal includes all issues in the field of Power Electronics and drive systems. Included are techniques for advanced power semiconductor devices, control in power electronics, low and high power converters (inverters, converters, controlled and uncontrolled rectifiers), Control algorithms and techniques applied to power electronics, electromagnetic and thermal performance of electronic power converters and inverters, power quality and utility applications, renewable energy, electric machines, modelling, simulation, analysis, design and implementations of the application of power circuit components (power semiconductors, inductors, high frequency transformers, capacitors), EMI/EMC considerations, power devices and components, sensors, integration and packaging, applications in motor drives, wind energy systems, solar, battery chargers, UPS and hybrid systems and other applications.