Investigation of Biomimetic Adaptive Mechanisms for Hybrid Power Plant Control

Q1 Mathematics

International Review of Automatic Control Pub Date : 2017-09-30 DOI:10.15866/IREACO.V10I5.12415

Ghassan Al-Sinbol, M. Perhinschi, Paolo Pezzini, K. Bryden, D. Tucker

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引用次数: 2

Abstract

In this paper, biologically inspired adaptive control mechanisms are investigated for highly integrated, complex energy plants. The adaptive mechanisms are designed to augment the performance and robustness of baseline control laws under normal and abnormal operating conditions. Novel artificial neural network-based and artificial immune system-based approaches are developed and investigated for an advanced power plant through linear model simulation. Abnormal conditions are simulated by altering the parameters of the transfer functions (gains, delays, and time constants). The performance metrics used to analyze the different control solutions include integral and mean of absolute value of tracking error and overshoot. Comparative results demonstrate the promising capability of the biomimetic adaptive mechanisms to increase robustness of baseline control laws under plant abnormalities. The proposed approach creates premises for the development of comprehensive technologies for complex power plant control with high performance within nominal and outside design boundaries.

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混合电厂控制的仿生自适应机制研究

本文研究了高度集成、复杂能源植物的生物启发自适应控制机制。自适应机制被设计为在正常和异常操作条件下增强基线控制律的性能和鲁棒性。通过线性模型仿真，开发并研究了基于人工神经网络和人工免疫系统的先进发电厂新方法。通过改变传递函数的参数（增益、延迟和时间常数）来模拟异常情况。用于分析不同控制解决方案的性能指标包括跟踪误差和超调的绝对值的积分和平均值。比较结果证明了仿生自适应机制在植物异常情况下提高基线控制律稳健性的良好能力。所提出的方法为开发在标称和设计边界外具有高性能的复杂发电厂控制综合技术创造了前提。

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

International Review of Automatic Control Engineering-Control and Systems Engineering

CiteScore

2.70

自引率

0.00%

发文量