Design of a Wide-Area Damping Controller Based on Fuzzy Control

Lin Sun; Wei Cai; Tian Ran Li; Hua Ren Wu

doi:10.4028/www.scientific.net/AMR.960-961.960

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Analysis and Prevention of Grid Over-Voltage Ferromagnetic Resonance
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Nanometer Interconnect Test Structure for Modeling of Process Variation
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A Novel Genetic Algorithm Based on all Spanning Trees of Undirected Graph for Distribution Network Reconfiguration
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Aggregation of Loads with Distribution Network Considered
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Design of a Wide-Area Damping Controller Based on Fuzzy Control
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Distribution Network Planning Based on Multi-Island Group Strategy Genetic Algorithm
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Experimental Investigation of Static Load Characteristics
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Research and Application of Medium-Speed Pulverizer Control Based on AGC Mode
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A Electronic Control Stirling Engine Fuel Supply System Based on Real-Time Operating System
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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 960-961Design of a Wide-Area Damping Controller Based on...

Design of a Wide-Area Damping Controller Based on Fuzzy Control

Abstract:

A method is proposed to design a wide-area damping controller (WADC) based on fuzzy control to dampen the low-frequency oscillations of interconnected power systems. First, the inputs and expected outputs of a fuzzy logic controller are analyzed. Then, a universe of fuzzy sets, membership functions and fuzzy rules are determined based on the relationship between inputs and outputs, and the fuzzy logic controller is constituted. The WADC consists of a fuzzy logic controller and a gain. The gain is obtained using particle swarm optimization. A four-machine two-area power system is simulated using the Matlab/Simulink software to test the performance of the fuzzy-based WADC. The simulation results indicate that the designed controller can compensate for communication delay and improve interconnected power system damping.