Short term load forecasting with markovian switching distributed deep belief networks
Short term load forecasting with markovian switching distributed deep belief networks
In modern power systems, centralised short term load forecasting (STLF) methods raise concern on high communication requirements and reliability when a central controller undertakes the processing of massive load data solely. As an alternative, distributed methods avoid the problems mentioned above, whilst the possible issues of cyberattacks and uncertain forecasting accuracy still exist. To address the two issues, a novel distributed deep belief networks (DDBN) with Markovian switching topology is proposed for an accurate STLF, based on a completely distributed framework. Without the central governor, the load dataset is separated and the model is trained locally, while obtaining the updates through communication with stochastic neighbours under a designed consensus procedure, and therefore significantly reduced the training time. The overall network reliability against cyberattacks is enhanced by continually switching communication topologies. In the meanwhile, to ensure that the distributed structure is still stable under such a varying topology, the consensus controller gain is delicately designed, and the convergence of the proposed algorithm is theoretically analysed via the Lyapunov function. Besides, restricted Boltzmann machines (RBM) based unsupervised learning is employed for DDBN initialisation and thereby guaranteeing the success rate of STLF model training. GEFCom 2017 competition and ISO New England load datasets are applied to validate the accuracy and effectiveness of the proposed method. Experiment results demonstrate that the proposed DDBN algorithm can enhance around 19% better forecasting accuracy than centralised DBN algorithm.
Distributed deep belief networks, Distributed solution, Electricity load demand, Markovian switching consensus algorithm, Short term load forecasting
Dong, Yi
355a62d9-5d1a-4c14-a900-9911e8c62453
Dong, Zhen
aba7081a-fba2-470f-a954-29603012f666
Zhao, Tianqiao
f8932503-8fa9-456e-b600-e0b420dcce0f
Li, Zhongguo
4e946c87-2de7-4e95-9a45-3d5f7853f78e
Ding, Zhengtao
5589b7c6-eadd-4383-885f-bcc2017f71b8
30 March 2021
Dong, Yi
355a62d9-5d1a-4c14-a900-9911e8c62453
Dong, Zhen
aba7081a-fba2-470f-a954-29603012f666
Zhao, Tianqiao
f8932503-8fa9-456e-b600-e0b420dcce0f
Li, Zhongguo
4e946c87-2de7-4e95-9a45-3d5f7853f78e
Ding, Zhengtao
5589b7c6-eadd-4383-885f-bcc2017f71b8
Dong, Yi, Dong, Zhen, Zhao, Tianqiao, Li, Zhongguo and Ding, Zhengtao
(2021)
Short term load forecasting with markovian switching distributed deep belief networks.
International Journal of Electrical Power and Energy Systems, 130, [106942].
(doi:10.1016/j.ijepes.2021.106942).
Abstract
In modern power systems, centralised short term load forecasting (STLF) methods raise concern on high communication requirements and reliability when a central controller undertakes the processing of massive load data solely. As an alternative, distributed methods avoid the problems mentioned above, whilst the possible issues of cyberattacks and uncertain forecasting accuracy still exist. To address the two issues, a novel distributed deep belief networks (DDBN) with Markovian switching topology is proposed for an accurate STLF, based on a completely distributed framework. Without the central governor, the load dataset is separated and the model is trained locally, while obtaining the updates through communication with stochastic neighbours under a designed consensus procedure, and therefore significantly reduced the training time. The overall network reliability against cyberattacks is enhanced by continually switching communication topologies. In the meanwhile, to ensure that the distributed structure is still stable under such a varying topology, the consensus controller gain is delicately designed, and the convergence of the proposed algorithm is theoretically analysed via the Lyapunov function. Besides, restricted Boltzmann machines (RBM) based unsupervised learning is employed for DDBN initialisation and thereby guaranteeing the success rate of STLF model training. GEFCom 2017 competition and ISO New England load datasets are applied to validate the accuracy and effectiveness of the proposed method. Experiment results demonstrate that the proposed DDBN algorithm can enhance around 19% better forecasting accuracy than centralised DBN algorithm.
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Accepted/In Press date: 19 February 2021
Published date: 30 March 2021
Additional Information:
Publisher Copyright:
© 2021 Elsevier Ltd
Keywords:
Distributed deep belief networks, Distributed solution, Electricity load demand, Markovian switching consensus algorithm, Short term load forecasting
Identifiers
Local EPrints ID: 484089
URI: http://eprints.soton.ac.uk/id/eprint/484089
ISSN: 0142-0615
PURE UUID: e5d76d92-5662-499d-ae3b-f09b10eedf09
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Date deposited: 09 Nov 2023 18:18
Last modified: 18 Mar 2024 04:17
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Contributors
Author:
Yi Dong
Author:
Zhen Dong
Author:
Tianqiao Zhao
Author:
Zhongguo Li
Author:
Zhengtao Ding
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