Design of controllers for electrical power systems using a complex root locus method
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A large class of three-phase electrical power systems possess symmetry conditions that make it possible to describe their behavior using single-input single-output transfer functions with complex coefficients. In such cases, an extended root locus method can be used to design control laws, even though the actual systems are multi-input multi-output. In this paper, the symmetric conditions for a large class of power systems are analyzed. Then, the root locus method is revisited for systems with complex coeffcients and used for the analysis and control design of power systems. To demonstrate the benefits of the approach, this paper includes two examples: 1) a doubly fed induction machine and 2) a three-phase LCL inverter.
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CitationDoria-Cerezo, A., Bodson, M. Design of controllers for electrical power systems using a complex root locus method. "(0278-0046) IEEE transactions on industrial electronics", 1 Juny 2016, vol. 63, núm. 6, p. 3706-3716.