{"title":"LTI 系统的模型阶数缩减策略及其在 PID 控制器设计中的应用","authors":"Bala Bhaskar Duddeti","doi":"10.1007/s00034-024-02825-9","DOIUrl":null,"url":null,"abstract":"<p>The mathematical modeling of the real-time system results in large-dimensional ordinary or partial differential equations, which are challenging to employ for investigation and control synthesis. Finding a comparable system of the same kind in a lower-order dimension that can maintain the core characteristics of the higher-order system (HOS) is essential. This article discusses a novel technique for HOS’s reduced order approximation and control design. The proposed method modifies the Schur method for balanced truncation. The method circumvents the requirement of balancing transformation and steady-state gain (SSG) deviation as required in the truncated model reduction algorithm. The offered technique eliminates the SSG deviation without altering the dynamical behavior compared to the HOS by appending a gain enhancement factor to the numerator polynomial of the reduced system transfer matrix. The offered technique ensures that the reduced system retains the HOS stability, passivity, SSG, and all critical characteristics. The recommended method’s findings are compared to the outcomes of recently published work’s lower-order models. Further, using the proposed method, the reduced model has been used to design a PID controller for the flexible-missile control model and an automatic voltage regulator system. The controller produced using the simplified model provides almost the exact time domain specifications (TDS) as the controller made using the HOS, and its design is also relatively more straightforward. Step response and TDS assess lower- and higher-order controller performance.</p>","PeriodicalId":10227,"journal":{"name":"Circuits, Systems and Signal Processing","volume":null,"pages":null},"PeriodicalIF":1.8000,"publicationDate":"2024-08-27","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Model Order Reduction Strategy for LTI Systems and Application to PID Controller Design\",\"authors\":\"Bala Bhaskar Duddeti\",\"doi\":\"10.1007/s00034-024-02825-9\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>The mathematical modeling of the real-time system results in large-dimensional ordinary or partial differential equations, which are challenging to employ for investigation and control synthesis. Finding a comparable system of the same kind in a lower-order dimension that can maintain the core characteristics of the higher-order system (HOS) is essential. This article discusses a novel technique for HOS’s reduced order approximation and control design. The proposed method modifies the Schur method for balanced truncation. The method circumvents the requirement of balancing transformation and steady-state gain (SSG) deviation as required in the truncated model reduction algorithm. The offered technique eliminates the SSG deviation without altering the dynamical behavior compared to the HOS by appending a gain enhancement factor to the numerator polynomial of the reduced system transfer matrix. The offered technique ensures that the reduced system retains the HOS stability, passivity, SSG, and all critical characteristics. The recommended method’s findings are compared to the outcomes of recently published work’s lower-order models. Further, using the proposed method, the reduced model has been used to design a PID controller for the flexible-missile control model and an automatic voltage regulator system. The controller produced using the simplified model provides almost the exact time domain specifications (TDS) as the controller made using the HOS, and its design is also relatively more straightforward. 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引用次数: 0
摘要
实时系统的数学建模会产生大维度的常微分方程或偏微分方程,这对研究和控制合成是一个挑战。在低阶维度上找到一个能保持高阶系统(HOS)核心特性的同类可比系统至关重要。本文讨论了一种用于高阶系统低阶近似和控制设计的新技术。所提出的方法修改了用于平衡截断的舒尔方法。该方法规避了截断模型缩减算法中平衡变换和稳态增益(SSG)偏差的要求。与 HOS 相比,所提供的技术通过在还原系统传递矩阵的分子多项式中附加增益增强因子,消除了 SSG 偏差,同时不改变动力学行为。所提供的技术可确保简化系统保持 HOS 的稳定性、被动性、SSG 和所有关键特性。建议方法的结果与最近发表的低阶模型结果进行了比较。此外,利用建议的方法,简化模型已被用于为柔性导弹控制模型和自动电压调节器系统设计 PID 控制器。使用简化模型制作的控制器与使用 HOS 制作的控制器具有几乎完全相同的时域规格(TDS),而且其设计也相对更加简单。阶跃响应和 TDS 评估了低阶和高阶控制器的性能。
Model Order Reduction Strategy for LTI Systems and Application to PID Controller Design
The mathematical modeling of the real-time system results in large-dimensional ordinary or partial differential equations, which are challenging to employ for investigation and control synthesis. Finding a comparable system of the same kind in a lower-order dimension that can maintain the core characteristics of the higher-order system (HOS) is essential. This article discusses a novel technique for HOS’s reduced order approximation and control design. The proposed method modifies the Schur method for balanced truncation. The method circumvents the requirement of balancing transformation and steady-state gain (SSG) deviation as required in the truncated model reduction algorithm. The offered technique eliminates the SSG deviation without altering the dynamical behavior compared to the HOS by appending a gain enhancement factor to the numerator polynomial of the reduced system transfer matrix. The offered technique ensures that the reduced system retains the HOS stability, passivity, SSG, and all critical characteristics. The recommended method’s findings are compared to the outcomes of recently published work’s lower-order models. Further, using the proposed method, the reduced model has been used to design a PID controller for the flexible-missile control model and an automatic voltage regulator system. The controller produced using the simplified model provides almost the exact time domain specifications (TDS) as the controller made using the HOS, and its design is also relatively more straightforward. Step response and TDS assess lower- and higher-order controller performance.
期刊介绍:
Rapid developments in the analog and digital processing of signals for communication, control, and computer systems have made the theory of electrical circuits and signal processing a burgeoning area of research and design. The aim of Circuits, Systems, and Signal Processing (CSSP) is to help meet the needs of outlets for significant research papers and state-of-the-art review articles in the area.
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