Title :
Predictability of back propagation and discrete Hopfield neural networks in harmonic compensation systems
Author :
Lin, Hsiung Cheng ; Lee, Cheng Song
Author_Institution :
Sch. of Biophys. Sci. & Electr. Eng., Swinburne Univ. of Technol., Hawthorn, Vic., Australia
Abstract :
A quality tool for predicting control signals is indispensable for effective harmonic compensation in AC power distribution systems. Notably in the literature, either back propagation (BP) or Hopfield neural networks (HNN) has claimed to provide quality control signals to achieve the desired harmonic reduction results. This paper evaluates the predictability of BP and HNN in terms of convergence behaviour and learning capability, as applied to the reduction of load generated current harmonics in a variable speed DC drive. Using the same real current harmonic data, our test results confirm that BP has a larger dynamic harmonic range whereas discrete HNN, due to its interconnection structure, needs larger size of memory map
Keywords :
DC motor drives; Hopfield neural nets; backpropagation; compensation; convergence; distribution networks; harmonics suppression; power engineering computing; power system harmonics; variable speed drives; AC power distribution systems; back propagation neural networks; control signals prediction; convergence behaviour; discrete Hopfield neural networks; dynamic harmonic range; harmonic compensation systems; harmonic reduction; interconnection structure; learning capability; load generated current harmonics reduction; quality tool; real current harmonic data; variable speed DC drive; Active filters; Control systems; DC generators; Filtering; Hopfield neural networks; Intelligent networks; Neural networks; Passive filters; Power harmonic filters; Power system harmonics;
Conference_Titel :
Power System Technology, 2000. Proceedings. PowerCon 2000. International Conference on
Conference_Location :
Perth, WA
Print_ISBN :
0-7803-6338-8
DOI :
10.1109/ICPST.2000.900080
