Title :
Practical design of a three-phase active power-line conditioner controlled by artificial neural networks
Author :
Salmerón, Patricio ; Vázquez, Jesús R.
Author_Institution :
Dept. of Electr. Eng., Huelva Univ., Palos De La Frontera, Spain
fDate :
4/1/2005 12:00:00 AM
Abstract :
Today, there is an increase of harmonic pollution in electrical systems due to the use of nonlinear loads. Thus, the current and voltage waveforms are nonsinusoidal. The active power-line conditioners (APLCs) are used to compensate the generated harmonics and to correct the load power factor. In this paper, a new APLC control design based on artificial neural networks is developed. Adaptive networks estimate the control reference compensation currents, and a feedforward network (trained by a backpropagation algorithm) implements the pulsewidth-modulation (PWM) control method used. An experimental prototype was built to test the proposed design. The practical results confirm the possibility and usefulness of controlling an APLC by means of artificial neural networks.
Keywords :
PWM invertors; active filters; adaptive control; backpropagation; control system synthesis; electric current control; feedforward neural nets; harmonic distortion; neurocontrollers; power factor; power harmonic filters; power transmission lines; APLC control design; active filters; adaptive control; artificial neural network; backpropagation control; conditioner control; electrical system harmonic pollution; feedforward network; harmonic distortion; load power factor; nonlinear loads; reference compensation current control; Adaptive systems; Artificial neural networks; Control design; Pollution; Power generation; Power system harmonics; Programmable control; Pulse width modulation; Reactive power; Voltage; ART neural networks; Active filters; adaptive control; backpropagation; compensation; harmonic distortion; power electronics; reactive power;
Journal_Title :
Power Delivery, IEEE Transactions on
DOI :
10.1109/TPWRD.2004.838513
