Optimization of a comb-like beam piezoelectric energy harvester using the parallel separated multi-input neural network surrogate model
Optimization of a comb-like beam piezoelectric energy harvester using the parallel separated multi-input neural network surrogate model
This paper proposes a novel parallel separated multi-input neural network (PSMNN) surrogate model that is used to optimize a comb-like beam piezoelectric energy harvester (CB-PEH) considering multi-parameter. The performance index of optimization is defined as a weighted average of the average output power, maximum output power, and total structural mass of the CB-PEH across 15 optimization parameters. The PSMNN surrogate model conducts parallel separation of inputs, which boosts feature extraction and reduces network complexity, achieving over 98 % accuracy in predicting average output power based on datasets obtained from the finite element model (FEM). The genetic algorithm based on the PSMNN model instead of the rough theoretical derivation and time-consuming FEM process achieved the desired performance improvement. Results show that PSMNN outperforms the traditional fully connected layer (FCL) network in terms of regression prediction accuracy ((increased by 3.03 %) and lower network complexity (reduced by 33.10 %). Compared with the structure before and after optimization, the maximum output power is increased by 152.99 %, the average output power is increased by 32.33 %, and the total structure mass is reduced by 9.69 %. Finally, experimental validation confirms the performance improvement of optimization, with the open-circuit voltage of the optimized CB-PEH increasing by 285.27 %.
piezoelectric, energy harvester, deep learning, genetic algorithm, design automation, optimization
Ren, Mengyuan
6f8aadf8-b692-4c8c-8465-9f7eed4b57e6
Wang, Chuankui
a06983d2-da6e-4741-acd2-1d95e7525c09
Moshrefi-Torbati, Mohamed
65b351dc-7c2e-4a9a-83a4-df797973913b
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Shu, Yucheng
562819b5-d6bd-47b0-92fa-6de799dfcbef
Yang, Kai
5cd33328-32e6-40a1-816c-416544141bb1
25 September 2025
Ren, Mengyuan
6f8aadf8-b692-4c8c-8465-9f7eed4b57e6
Wang, Chuankui
a06983d2-da6e-4741-acd2-1d95e7525c09
Moshrefi-Torbati, Mohamed
65b351dc-7c2e-4a9a-83a4-df797973913b
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Shu, Yucheng
562819b5-d6bd-47b0-92fa-6de799dfcbef
Yang, Kai
5cd33328-32e6-40a1-816c-416544141bb1
Ren, Mengyuan, Wang, Chuankui, Moshrefi-Torbati, Mohamed, Yurchenko, Daniil, Shu, Yucheng and Yang, Kai
(2025)
Optimization of a comb-like beam piezoelectric energy harvester using the parallel separated multi-input neural network surrogate model.
Mechanical Systems and Signal Processing, 224, [111939].
(doi:10.1016/j.ymssp.2024.111939).
Abstract
This paper proposes a novel parallel separated multi-input neural network (PSMNN) surrogate model that is used to optimize a comb-like beam piezoelectric energy harvester (CB-PEH) considering multi-parameter. The performance index of optimization is defined as a weighted average of the average output power, maximum output power, and total structural mass of the CB-PEH across 15 optimization parameters. The PSMNN surrogate model conducts parallel separation of inputs, which boosts feature extraction and reduces network complexity, achieving over 98 % accuracy in predicting average output power based on datasets obtained from the finite element model (FEM). The genetic algorithm based on the PSMNN model instead of the rough theoretical derivation and time-consuming FEM process achieved the desired performance improvement. Results show that PSMNN outperforms the traditional fully connected layer (FCL) network in terms of regression prediction accuracy ((increased by 3.03 %) and lower network complexity (reduced by 33.10 %). Compared with the structure before and after optimization, the maximum output power is increased by 152.99 %, the average output power is increased by 32.33 %, and the total structure mass is reduced by 9.69 %. Finally, experimental validation confirms the performance improvement of optimization, with the open-circuit voltage of the optimized CB-PEH increasing by 285.27 %.
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Optimization of a comb-like beam
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Accepted/In Press date: 9 September 2024
e-pub ahead of print date: 25 September 2024
Published date: 25 September 2025
Keywords:
piezoelectric, energy harvester, deep learning, genetic algorithm, design automation, optimization
Identifiers
Local EPrints ID: 498107
URI: http://eprints.soton.ac.uk/id/eprint/498107
ISSN: 0888-3270
PURE UUID: 2d315e92-e69a-46d0-9fe3-2431e40e27fe
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Date deposited: 10 Feb 2025 17:36
Last modified: 27 Feb 2025 03:03
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Author:
Mengyuan Ren
Author:
Chuankui Wang
Author:
Daniil Yurchenko
Author:
Yucheng Shu
Author:
Kai Yang
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