Title :
Control of Turbine and Excitation in Power System Based on Neural Networks
Author :
Li, Hongbiao ; Yin, Lixin
Author_Institution :
Sch. of Inf. Eng., Northeast Dianli Univ., Jilin, China
Abstract :
Increasingly nonlinear dynamic loads have been connected into power systems; such as variable speed drives, robotic factories and power electronics loads. This adds to the complexity of load modeling. The increasing complexity of the modern power grid highlights the need for advanced modeling and control techniques for effective control of excitation and turbine systems. The crucial factors affecting the modern power systems today is voltage control and system stabilization during small and large disturbances. Simulation studies and real-time laboratory experimental studies carried out are described and the results show the successful control of the power system excitation and turbine systems with adaptive and optimal neurocontrol approaches.
Keywords :
adaptive control; load regulation; neurocontrollers; nonlinear dynamical systems; optimal control; power grids; power system control; power system faults; power system stability; turbines; variable speed drives; voltage control; adaptive control; advanced modeling; control techniques; large disturbance; load modeling; neural networks; nonlinear dynamic loads; optimal neurocontrol; power electronics loads; power grid; power system excitation; power systems; robotic factory; small disturbance; system stabilization; turbine control; turbine systems; variable speed drives; voltage control; Adaptation model; Artificial neural networks; DH-HEMTs; Load modeling; Power system dynamics; Training; artificial neural networks; excitation control; load model-ing; reinforcement learning; stability analysis; turbine control;
Conference_Titel :
Electrical and Control Engineering (ICECE), 2010 International Conference on
Conference_Location :
Wuhan
Print_ISBN :
978-1-4244-6880-5
DOI :
10.1109/iCECE.2010.848
