DeepOPF-AL: Augmented Learning for Solving AC-OPF Problems with a Multi-Valued Load-Solution Mapping

Xiang Pan; Wanjun Huang; Minghua Chen; Steven H. Low

doi:10.1145/3575813.3576874

DeepOPF-AL: Augmented Learning for Solving AC-OPF Problems with a Multi-Valued Load-Solution Mapping

Xiang Pan, Wanjun Huang, Minghua Chen, Steven H. Low

Department of Data Science

Research output: Chapters, Conference Papers, Creative and Literary Works › RGC 32 - Refereed conference paper (with host publication) › peer-review

11 Citations (Scopus)

Abstract

The existence of multi-valued load-solution mapping in general non-convex problems poses a fundamental challenge to deep neural network (DNN) schemes. A well-trained DNN in the existing supervised learning framework fails to learn the multi-valued mapping accurately and generates inferior solutions. We propose augmented learning as a methodological framework to tackle this challenge. We focus on AC-OPF as an important example and develop DeepOPF-AL to solve it. The main idea is to train a DNN to learn a single-valued mapping from an augmented input, i.e., (load, initial point), to the solution generated by an iterative OPF solver with the load and initial point as intake. We then apply the learned augmented mapping to solve AC-OPF problems much faster than conventional solvers. Simulation results over IEEE test cases show that DeepOPF-AL achieves noticeably better optimality and similar feasibility and speedup performance as compared to a recent DNN scheme, with the same DNN size yet larger training-data size. We believe the augmented-learning approach will find applications in various problems with a multi-valued input-solution mapping. © 2023 ACM.

Original language	English
Title of host publication	e-Energy '23 - Proceedings of the 2023 The 14th ACM International Conference on Future Energy Systems
Place of Publication	New York, NY
Publisher	Association for Computing Machinery
Pages	42-47
Number of pages	6
ISBN (Print)	9798400700323
DOIs	https://doi.org/10.1145/3575813.3576874
Publication status	Published - 2023
Event	14th ACM International Conference on Future Energy Systems (ACM e-Energy 2023) - Orlando, United States Duration: 20 Jun 2023 → 23 Jun 2023 https://energy.acm.org/conferences/eenergy/2023/program.php

Publication series

Name	e-Energy - Proceedings of the ACM International Conference on Future Energy Systems

Conference

Conference	14th ACM International Conference on Future Energy Systems (ACM e-Energy 2023)
Abbreviated title	e-Energy 2023
Place	United States
City	Orlando
Period	20/06/23 → 23/06/23
Internet address	https://energy.acm.org/conferences/eenergy/2023/program.php

Research Keywords

AC optimal power flow
augmented learning
deep neural network

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10.1145/3575813.3576874

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Pan, X., Huang, W., Chen, M., & Low, S. H. (2023). DeepOPF-AL: Augmented Learning for Solving AC-OPF Problems with a Multi-Valued Load-Solution Mapping. In e-Energy '23 - Proceedings of the 2023 The 14th ACM International Conference on Future Energy Systems (pp. 42-47). (e-Energy - Proceedings of the ACM International Conference on Future Energy Systems). Association for Computing Machinery. https://doi.org/10.1145/3575813.3576874

Pan, Xiang ; Huang, Wanjun ; Chen, Minghua et al. / DeepOPF-AL : Augmented Learning for Solving AC-OPF Problems with a Multi-Valued Load-Solution Mapping. e-Energy '23 - Proceedings of the 2023 The 14th ACM International Conference on Future Energy Systems. New York, NY : Association for Computing Machinery, 2023. pp. 42-47 (e-Energy - Proceedings of the ACM International Conference on Future Energy Systems).

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abstract = "The existence of multi-valued load-solution mapping in general non-convex problems poses a fundamental challenge to deep neural network (DNN) schemes. A well-trained DNN in the existing supervised learning framework fails to learn the multi-valued mapping accurately and generates inferior solutions. We propose augmented learning as a methodological framework to tackle this challenge. We focus on AC-OPF as an important example and develop DeepOPF-AL to solve it. The main idea is to train a DNN to learn a single-valued mapping from an augmented input, i.e., (load, initial point), to the solution generated by an iterative OPF solver with the load and initial point as intake. We then apply the learned augmented mapping to solve AC-OPF problems much faster than conventional solvers. Simulation results over IEEE test cases show that DeepOPF-AL achieves noticeably better optimality and similar feasibility and speedup performance as compared to a recent DNN scheme, with the same DNN size yet larger training-data size. We believe the augmented-learning approach will find applications in various problems with a multi-valued input-solution mapping. {\textcopyright} 2023 ACM.",

keywords = "AC optimal power flow, augmented learning, deep neural network",

author = "Xiang Pan and Wanjun Huang and Minghua Chen and Low, {Steven H.}",

year = "2023",

doi = "10.1145/3575813.3576874",

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series = "e-Energy - Proceedings of the ACM International Conference on Future Energy Systems",

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booktitle = "e-Energy '23 - Proceedings of the 2023 The 14th ACM International Conference on Future Energy Systems",

address = "United States",

note = "14th ACM International Conference on Future Energy Systems (ACM e-Energy 2023), e-Energy 2023 ; Conference date: 20-06-2023 Through 23-06-2023",

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Pan, X, Huang, W, Chen, M & Low, SH 2023, DeepOPF-AL: Augmented Learning for Solving AC-OPF Problems with a Multi-Valued Load-Solution Mapping. in e-Energy '23 - Proceedings of the 2023 The 14th ACM International Conference on Future Energy Systems. e-Energy - Proceedings of the ACM International Conference on Future Energy Systems, Association for Computing Machinery, New York, NY, pp. 42-47, 14th ACM International Conference on Future Energy Systems (ACM e-Energy 2023), Orlando, Florida, United States, 20/06/23. https://doi.org/10.1145/3575813.3576874

DeepOPF-AL: Augmented Learning for Solving AC-OPF Problems with a Multi-Valued Load-Solution Mapping. / Pan, Xiang; Huang, Wanjun; Chen, Minghua et al.
e-Energy '23 - Proceedings of the 2023 The 14th ACM International Conference on Future Energy Systems. New York, NY: Association for Computing Machinery, 2023. p. 42-47 (e-Energy - Proceedings of the ACM International Conference on Future Energy Systems).

Research output: Chapters, Conference Papers, Creative and Literary Works › RGC 32 - Refereed conference paper (with host publication) › peer-review

TY - GEN

T1 - DeepOPF-AL

T2 - 14th ACM International Conference on Future Energy Systems (ACM e-Energy 2023)

AU - Pan, Xiang

AU - Huang, Wanjun

AU - Chen, Minghua

AU - Low, Steven H.

PY - 2023

Y1 - 2023

N2 - The existence of multi-valued load-solution mapping in general non-convex problems poses a fundamental challenge to deep neural network (DNN) schemes. A well-trained DNN in the existing supervised learning framework fails to learn the multi-valued mapping accurately and generates inferior solutions. We propose augmented learning as a methodological framework to tackle this challenge. We focus on AC-OPF as an important example and develop DeepOPF-AL to solve it. The main idea is to train a DNN to learn a single-valued mapping from an augmented input, i.e., (load, initial point), to the solution generated by an iterative OPF solver with the load and initial point as intake. We then apply the learned augmented mapping to solve AC-OPF problems much faster than conventional solvers. Simulation results over IEEE test cases show that DeepOPF-AL achieves noticeably better optimality and similar feasibility and speedup performance as compared to a recent DNN scheme, with the same DNN size yet larger training-data size. We believe the augmented-learning approach will find applications in various problems with a multi-valued input-solution mapping. © 2023 ACM.

AB - The existence of multi-valued load-solution mapping in general non-convex problems poses a fundamental challenge to deep neural network (DNN) schemes. A well-trained DNN in the existing supervised learning framework fails to learn the multi-valued mapping accurately and generates inferior solutions. We propose augmented learning as a methodological framework to tackle this challenge. We focus on AC-OPF as an important example and develop DeepOPF-AL to solve it. The main idea is to train a DNN to learn a single-valued mapping from an augmented input, i.e., (load, initial point), to the solution generated by an iterative OPF solver with the load and initial point as intake. We then apply the learned augmented mapping to solve AC-OPF problems much faster than conventional solvers. Simulation results over IEEE test cases show that DeepOPF-AL achieves noticeably better optimality and similar feasibility and speedup performance as compared to a recent DNN scheme, with the same DNN size yet larger training-data size. We believe the augmented-learning approach will find applications in various problems with a multi-valued input-solution mapping. © 2023 ACM.

KW - AC optimal power flow

KW - augmented learning

KW - deep neural network

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UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-85163065659&origin=recordpage

U2 - 10.1145/3575813.3576874

DO - 10.1145/3575813.3576874

M3 - RGC 32 - Refereed conference paper (with host publication)

SN - 9798400700323

T3 - e-Energy - Proceedings of the ACM International Conference on Future Energy Systems

SP - 42

EP - 47

BT - e-Energy '23 - Proceedings of the 2023 The 14th ACM International Conference on Future Energy Systems

PB - Association for Computing Machinery

CY - New York, NY

Y2 - 20 June 2023 through 23 June 2023

ER -

Pan X, Huang W, Chen M, Low SH. DeepOPF-AL: Augmented Learning for Solving AC-OPF Problems with a Multi-Valued Load-Solution Mapping. In e-Energy '23 - Proceedings of the 2023 The 14th ACM International Conference on Future Energy Systems. New York, NY: Association for Computing Machinery. 2023. p. 42-47. (e-Energy - Proceedings of the ACM International Conference on Future Energy Systems). Epub 2023 Jun 16. doi: 10.1145/3575813.3576874

DeepOPF-AL: Augmented Learning for Solving AC-OPF Problems with a Multi-Valued Load-Solution Mapping

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