Astrophysics-based transit search optimization heuristics for parameter estimation of multi-frequency sinusoidal signals

Modern Physics Letters B Pub Date : 2024-04-01 DOI:10.1142/s0217984924503421

Naveed Ahmed Malik, Ching-Lung Chang, Naveed Ishtiaq Chaudhary, Muhammad Asif Zahoor Raja, Chi-Min Shu

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Abstract

This study investigates an astrophysics-based Transit search optimization algorithm (TSOA) for solving a challenging engineering problem. This innovative strategy uses the fundamentals of physics to improve the accuracy and efficacy of problem solving techniques. Harmonic distortions in power systems have become a massive challenge because of the nonlinear loads associated with the electrical power distribution system. Overheating of the equipment, motor failure, capacitor failure, and improper power metering are all issues caused by harmonic distortion. A new examination of the causes and consequences of these issues, as well as the status of hardware and software available for harmonic evaluation, is necessary in light of the unprecedented advancements in power electronic devices and their integration at all levels in the power and energy system. In order to estimate phase and amplitude simultaneously with a specified frequency, an objective function of power system harmonics is created. Keeping in mind the adverse effects of harmonics, parameter estimation is carried out under various conditions by taking different particle sizes and signal-to-noise ratios. TSOA proved its efficacy for both phase and amplitude parameters under different situations and precisely estimated the harmonics signal up to an accuracy of 1.1648E–15. Two harmonic signals were taken in this research work, and the best MSE values achieved are 9.748E–4, 8.287E–07, 6.157E–10, and 1.165E–15 for 30, 60, 90, and 150 dB noise, respectively, under case study 1 while varying the particle size from 50 to 450. The results for case study 2 proved to be best up to 7.373E–16, and no significant change occurred by increasing the generations above 500. The proposed study would be a step further in developing a more accurate and robust computing platform for robust estimation of harmonics arising in power and energy systems.

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基于天体物理学的过境搜索优化启发式方法，用于多频正弦信号的参数估计

本研究探讨了一种基于天体物理学的中转搜索优化算法（TSOA），用于解决一个具有挑战性的工程问题。这一创新策略利用物理学基础来提高问题解决技术的准确性和有效性。由于配电系统的非线性负载，电力系统中的谐波畸变已成为一个巨大的挑战。设备过热、电机故障、电容器故障和电能计量不当都是谐波畸变造成的问题。鉴于电力电子设备的空前发展及其在电力和能源系统各个层面的集成，有必要对这些问题的原因和后果以及用于谐波评估的硬件和软件的现状进行新的研究。为了在指定频率下同时估算相位和幅值，创建了电力系统谐波的目标函数。考虑到谐波的不利影响，在各种条件下通过不同的粒子大小和信噪比进行参数估计。TSOA 证明了其在不同情况下对相位和幅值参数的有效性，并能精确估计谐波信号，精度高达 1.1648E-15。在案例研究 1 中，在 30、60、90 和 150 dB 噪声下，当颗粒大小从 50 到 450 变化时，两次谐波信号的最佳 MSE 值分别为 9.748E-4、8.287E-07、6.157E-10 和 1.165E-15。案例研究 2 的最佳结果为 7.373E-16，增加到 500 代以上没有发生显著变化。拟议的研究将进一步开发更准确、更稳健的计算平台，用于稳健估计电力和能源系统中出现的谐波。

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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Modern Physics Letters B

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