Application of genetic-based neural networks to thermal unit commitment

Shyh Jier Huang; Ching Lien Huang

doi:10.1109/59.589634

Application of genetic-based neural networks to thermal unit commitment

Shyh Jier Huang, Ching Lien Huang

Department of Electrical Engineering

Research output: Contribution to journal › Article › peer-review

62 Citations (Scopus)

Abstract

A new approach using genetic algorithms based neural networks and dynamic programming (GANN-DP) to solve power system unit commitment problems is proposed in this paper. A set of feasible generator commitment schedule is first formulated by genetic-enhanced neural networks. These pre-committed schedules are then optimized by the dynamic programming technique. By the proposed approach, the learning stagnation is avoided. The neural network stability and accuracy are significantly increased. The computational performance of unit commitment in a power system is therefore highly improved. The proposed method has been tested on a practical Taiwan Power (Taipower) thermal system through the utility data. The results demonstrate the feasibility and practicality of this approach.

Original language	English
Pages (from-to)	654-660
Number of pages	7
Journal	IEEE Transactions on Power Systems
Volume	12
Issue number	2
DOIs	https://doi.org/10.1109/59.589634
Publication status	Published - 1997

All Science Journal Classification (ASJC) codes

Energy Engineering and Power Technology
Electrical and Electronic Engineering

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10.1109/59.589634

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title = "Application of genetic-based neural networks to thermal unit commitment",

abstract = "A new approach using genetic algorithms based neural networks and dynamic programming (GANN-DP) to solve power system unit commitment problems is proposed in this paper. A set of feasible generator commitment schedule is first formulated by genetic-enhanced neural networks. These pre-committed schedules are then optimized by the dynamic programming technique. By the proposed approach, the learning stagnation is avoided. The neural network stability and accuracy are significantly increased. The computational performance of unit commitment in a power system is therefore highly improved. The proposed method has been tested on a practical Taiwan Power (Taipower) thermal system through the utility data. The results demonstrate the feasibility and practicality of this approach.",

author = "Huang, {Shyh Jier} and Huang, {Ching Lien}",

note = "Funding Information: The authors would like to express their thanks to the financial support gwen by the National Science Council of ROC under contract number NSC84-2213-E-214-019 and the technical support from Taiwan Power Company.",

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AU - Huang, Shyh Jier

AU - Huang, Ching Lien

N1 - Funding Information: The authors would like to express their thanks to the financial support gwen by the National Science Council of ROC under contract number NSC84-2213-E-214-019 and the technical support from Taiwan Power Company.

PY - 1997

Y1 - 1997

N2 - A new approach using genetic algorithms based neural networks and dynamic programming (GANN-DP) to solve power system unit commitment problems is proposed in this paper. A set of feasible generator commitment schedule is first formulated by genetic-enhanced neural networks. These pre-committed schedules are then optimized by the dynamic programming technique. By the proposed approach, the learning stagnation is avoided. The neural network stability and accuracy are significantly increased. The computational performance of unit commitment in a power system is therefore highly improved. The proposed method has been tested on a practical Taiwan Power (Taipower) thermal system through the utility data. The results demonstrate the feasibility and practicality of this approach.

AB - A new approach using genetic algorithms based neural networks and dynamic programming (GANN-DP) to solve power system unit commitment problems is proposed in this paper. A set of feasible generator commitment schedule is first formulated by genetic-enhanced neural networks. These pre-committed schedules are then optimized by the dynamic programming technique. By the proposed approach, the learning stagnation is avoided. The neural network stability and accuracy are significantly increased. The computational performance of unit commitment in a power system is therefore highly improved. The proposed method has been tested on a practical Taiwan Power (Taipower) thermal system through the utility data. The results demonstrate the feasibility and practicality of this approach.

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Application of genetic-based neural networks to thermal unit commitment

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