Stabilization of Second-Order Non-Minimum Phase System With Delay via PI Controllers: Spectral Abscissa Optimization
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This paper addresses the stabilization of a general class of linear single-input/single-output (SISO) second-order non-minimum phase systems with input channel delays using Proportional-Integral (PI) controllers. Such systems arise in various applications, including power electronic circuits and biochemical reactors. The primary goal is to enhance system performance by determining optimal control gains that shift the spectral abscissa of the closed-loop system as far to the left as possible, thereby improving its decay rate. To achieve this, we introduce a geometric framework that characterizes the stability region of the closed-loop system in three distinct cases. Our main contribution is a systematic tuning approach to achieve the desired decay rate when feasible. Additionally, we discuss the controller%27s fragility and the delay margin of the closed-loop system to ensure practical applicability. The effectiveness of the proposed method is demonstrated through numerical simulations for each scenario. Finally, two practical case studies - a boiler steam drum and a DC-DC boost converter - are presented to illustrate the results%27 relevance in practice.
Linear systems; non-minimum phase; PI control; quasi-polynomials; spectral abscissa; time-delay Boiler control; Closed loop control systems; Delay circuits; Delay control systems; Invariance; Linear control systems; Optimal control systems; Polynomials; Three term control systems; Two term control systems; Closed-loop system; Decay rate; Non-minimum phase; Non-minimum phase systems; Proportional integral controllers; Proportional-integral control; Quasipolynomials; Second orders; Spectral abscissum; Time-delays; Proportional control systems
