Risk-Based Design Optimization via Scenario Generation and Genetic Programming Under Hybrid Uncertainties

Wei Li; Xiaowei Zhou; Haihong Huang; Akhil Garg; Liang Gao

doi:10.1115/1.4065793

Risk-Based Design Optimization via Scenario Generation and Genetic Programming Under Hybrid Uncertainties

Wei Li, Xiaowei Zhou, Haihong Huang^*, Akhil Garg, Liang Gao

^*Corresponding author for this work

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

Abstract

The design of complex systems often requires the incorporation of uncertainty optimization strategies to mitigate system failures resulting from multiple uncertainties during actual operation. Risk-based design optimization, as an alternative methodology that accounts for the balance between design cost and performance, has garnered significant attention and recognition. This paper presents a risk design optimization method for tackling hybrid uncertainties via scenario generation and genetic programming. The hybrid uncertainties are quantified through the scenario generation method to obtain risk assessment indicators. The genetic programming method is used to simulate the real output of the objective or constraints. To drive the optimization process, the sample-based discrete gradient expression is constructed, and the optimal scheme aligning the risk requirements is obtained. Three calculation examples of varying computing complexity are presented to verify the efficacy and usability of the suggested approach.

Original language	English
Article number	101001
Journal	Journal of Computing and Information Science in Engineering
Volume	24
Issue number	10
DOIs	https://doi.org/10.1115/1.4065793
Publication status	Published - 1 Oct 2024
Externally published	Yes

Keywords

computational foundations for engineering optimization
computer-aided design
design optimization
genetic programming
hybrid uncertainties
qualification
risk analysis

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Cite this

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title = "Risk-Based Design Optimization via Scenario Generation and Genetic Programming Under Hybrid Uncertainties",

abstract = "The design of complex systems often requires the incorporation of uncertainty optimization strategies to mitigate system failures resulting from multiple uncertainties during actual operation. Risk-based design optimization, as an alternative methodology that accounts for the balance between design cost and performance, has garnered significant attention and recognition. This paper presents a risk design optimization method for tackling hybrid uncertainties via scenario generation and genetic programming. The hybrid uncertainties are quantified through the scenario generation method to obtain risk assessment indicators. The genetic programming method is used to simulate the real output of the objective or constraints. To drive the optimization process, the sample-based discrete gradient expression is constructed, and the optimal scheme aligning the risk requirements is obtained. Three calculation examples of varying computing complexity are presented to verify the efficacy and usability of the suggested approach.",

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AU - Huang, Haihong

AU - Garg, Akhil

AU - Gao, Liang

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AB - The design of complex systems often requires the incorporation of uncertainty optimization strategies to mitigate system failures resulting from multiple uncertainties during actual operation. Risk-based design optimization, as an alternative methodology that accounts for the balance between design cost and performance, has garnered significant attention and recognition. This paper presents a risk design optimization method for tackling hybrid uncertainties via scenario generation and genetic programming. The hybrid uncertainties are quantified through the scenario generation method to obtain risk assessment indicators. The genetic programming method is used to simulate the real output of the objective or constraints. To drive the optimization process, the sample-based discrete gradient expression is constructed, and the optimal scheme aligning the risk requirements is obtained. Three calculation examples of varying computing complexity are presented to verify the efficacy and usability of the suggested approach.

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Risk-Based Design Optimization via Scenario Generation and Genetic Programming Under Hybrid Uncertainties

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