Efficient Multi-Physics Optimization of High-Speed EV Motors: Employing a Hybrid, Adaptive Surrogate-Assisted Strategy

Taek Hyo Nam; Tae Hyuk Ji; Young Ho Hwang; In Seok Song; Seok Won Jung; Sang Yong Jung

doi:10.1109/TMAG.2025.3612946

Efficient Multi-Physics Optimization of High-Speed EV Motors: Employing a Hybrid, Adaptive Surrogate-Assisted Strategy

Taek Hyo Nam
, Tae Hyuk Ji
, Young Ho Hwang
, In Seok Song
, Seok Won Jung
, Sang Yong Jung

Sungkyunkwan University

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

Abstract

The optimal design of high-speed electric vehicle (EV) motors requires simultaneously addressing both electromagnetic (EM) performance and mechanical stress (MS). Reducing the significant computational time associated with this multi-physics optimization, however, is a fundamental challenge. To address this challenge, this paper presents a hybrid, two-step adaptive strategy. As performing finite element analysis (FEA) for all physics is computationally burdensome, the proposed strategy applies a surrogate model exclusively to the MS analysis, while continuing to use FEA for EM analysis. The proposed process first employs an initially imprecise surrogate model as a statistical filter to intelligently narrow the design space, and then transitions to a full surrogate replacement for the expensive MS FEA evaluations once the model achieves high fidelity. This strategy was applied to the design of a high-speed EV propulsion motor using a particle swarm optimization algorithm. To validate its efficacy, the method was benchmarked against a baseline method that omits the initial adaptive filtering step. The results demonstrate a substantial reduction in total computational time while successfully yielding a final design.

Original language	English
Journal	IEEE Transactions on Magnetics
DOIs	https://doi.org/10.1109/TMAG.2025.3612946
State	Accepted/In press - 2025
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

Confidence interval
deep learning
electric vehicle propulsion motor
gaussian distribution
mechanical stress
multi-physics optimization
surrogate model

Access to Document

10.1109/TMAG.2025.3612946

Cite this

@article{f02d2d19b6b64690914f2516eda85c01,

title = "Efficient Multi-Physics Optimization of High-Speed EV Motors: Employing a Hybrid, Adaptive Surrogate-Assisted Strategy",

abstract = "The optimal design of high-speed electric vehicle (EV) motors requires simultaneously addressing both electromagnetic (EM) performance and mechanical stress (MS). Reducing the significant computational time associated with this multi-physics optimization, however, is a fundamental challenge. To address this challenge, this paper presents a hybrid, two-step adaptive strategy. As performing finite element analysis (FEA) for all physics is computationally burdensome, the proposed strategy applies a surrogate model exclusively to the MS analysis, while continuing to use FEA for EM analysis. The proposed process first employs an initially imprecise surrogate model as a statistical filter to intelligently narrow the design space, and then transitions to a full surrogate replacement for the expensive MS FEA evaluations once the model achieves high fidelity. This strategy was applied to the design of a high-speed EV propulsion motor using a particle swarm optimization algorithm. To validate its efficacy, the method was benchmarked against a baseline method that omits the initial adaptive filtering step. The results demonstrate a substantial reduction in total computational time while successfully yielding a final design.",

keywords = "Confidence interval, deep learning, electric vehicle propulsion motor, gaussian distribution, mechanical stress, multi-physics optimization, surrogate model",

author = "Nam, \{Taek Hyo\} and Ji, \{Tae Hyuk\} and Hwang, \{Young Ho\} and Song, \{In Seok\} and Jung, \{Seok Won\} and Jung, \{Sang Yong\}",

note = "Publisher Copyright: {\textcopyright} 1965-2012 IEEE.",

year = "2025",

doi = "10.1109/TMAG.2025.3612946",

language = "English",

journal = "IEEE Transactions on Magnetics",

issn = "0018-9464",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

}

TY - JOUR

T1 - Efficient Multi-Physics Optimization of High-Speed EV Motors

T2 - Employing a Hybrid, Adaptive Surrogate-Assisted Strategy

AU - Nam, Taek Hyo

AU - Ji, Tae Hyuk

AU - Hwang, Young Ho

AU - Song, In Seok

AU - Jung, Seok Won

AU - Jung, Sang Yong

PY - 2025

Y1 - 2025

N2 - The optimal design of high-speed electric vehicle (EV) motors requires simultaneously addressing both electromagnetic (EM) performance and mechanical stress (MS). Reducing the significant computational time associated with this multi-physics optimization, however, is a fundamental challenge. To address this challenge, this paper presents a hybrid, two-step adaptive strategy. As performing finite element analysis (FEA) for all physics is computationally burdensome, the proposed strategy applies a surrogate model exclusively to the MS analysis, while continuing to use FEA for EM analysis. The proposed process first employs an initially imprecise surrogate model as a statistical filter to intelligently narrow the design space, and then transitions to a full surrogate replacement for the expensive MS FEA evaluations once the model achieves high fidelity. This strategy was applied to the design of a high-speed EV propulsion motor using a particle swarm optimization algorithm. To validate its efficacy, the method was benchmarked against a baseline method that omits the initial adaptive filtering step. The results demonstrate a substantial reduction in total computational time while successfully yielding a final design.

AB - The optimal design of high-speed electric vehicle (EV) motors requires simultaneously addressing both electromagnetic (EM) performance and mechanical stress (MS). Reducing the significant computational time associated with this multi-physics optimization, however, is a fundamental challenge. To address this challenge, this paper presents a hybrid, two-step adaptive strategy. As performing finite element analysis (FEA) for all physics is computationally burdensome, the proposed strategy applies a surrogate model exclusively to the MS analysis, while continuing to use FEA for EM analysis. The proposed process first employs an initially imprecise surrogate model as a statistical filter to intelligently narrow the design space, and then transitions to a full surrogate replacement for the expensive MS FEA evaluations once the model achieves high fidelity. This strategy was applied to the design of a high-speed EV propulsion motor using a particle swarm optimization algorithm. To validate its efficacy, the method was benchmarked against a baseline method that omits the initial adaptive filtering step. The results demonstrate a substantial reduction in total computational time while successfully yielding a final design.

KW - Confidence interval

KW - deep learning

KW - electric vehicle propulsion motor

KW - gaussian distribution

KW - mechanical stress

KW - multi-physics optimization

KW - surrogate model

UR - https://www.scopus.com/pages/publications/105017448937

U2 - 10.1109/TMAG.2025.3612946

DO - 10.1109/TMAG.2025.3612946

M3 - Article

AN - SCOPUS:105017448937

SN - 0018-9464

JO - IEEE Transactions on Magnetics

JF - IEEE Transactions on Magnetics

ER -

Efficient Multi-Physics Optimization of High-Speed EV Motors: Employing a Hybrid, Adaptive Surrogate-Assisted Strategy

Abstract

UN SDGs

Keywords

Access to Document

Other files and links

Fingerprint

Cite this