Automated multiphysics MEMS co-optimization platform: Integrated fabrication constraints and accelerated design for high-linearity sensors

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Automated multiphysics MEMS co-optimization platform: Integrated fabrication constraints and accelerated design for high-linearity sensors

Peizhi Yu et al · AIP Publishing LLC · 2026

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Autor / responsable

Peizhi Yu et al

Editorial

AIP Publishing LLC

Año

2026

ISSN

1672-6030

ISSN

1672-6030

Idioma

eng

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This paper proposes an innovative automated multiphysics Microelectromechanical systems (MEMS) co-optimization platform integrating the embedded reduced-order modeling offered by Coventor MEMS+ with MATLAB’s numerical computing environment, addressing critical limitations in conventional design workflows. Our framework demonstrates three key advances. First, the platform enables systematic co-optimization of structural parameters (comb geometries and suspension beams) through constrained design space exploration, achieving an order-of-magnitude improvement in sensor linearity while maintaining baseline sensitivity as validated by accelerometer case studies. Second, the implementation of manufacturing-aware optimization incorporates process tolerance constraints and geometric feasibility checks, effectively bridging the gap between simulation-based optimization and physical fabrication requirements. Third, comprehensive algorithm benchmarking reveals that the modified Nelder–Mead method achieves a superior convergence efficiency (∼100× computational efficiency) compared with evolutionary algorithms, while maintaining design quality, providing critical advantages for rapid MEMS prototyping. The platform establishes a new paradigm for MEMS co-design through tight integration of multiphysics simulation, manufacturing constraints, and intelligent optimization algorithms.

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APA 7

al, P. Y. E. (2026). Automated multiphysics MEMS co-optimization platform: Integrated fabrication constraints and accelerated design for high-linearity sensors. https://doi.org/10.1063/5.0299387

MLA

al, Peizhi Yu et. "Automated multiphysics MEMS co-optimization platform: Integrated fabrication constraints and accelerated design for high-linearity sensors." 2026. https://doi.org/10.1063/5.0299387.

Chicago

al, Peizhi Yu et. 2026. "Automated multiphysics MEMS co-optimization platform: Integrated fabrication constraints and accelerated design for high-linearity sensors.". https://doi.org/10.1063/5.0299387.

Harvard

al, P. Y. E. 2026, Automated multiphysics MEMS co-optimization platform: Integrated fabrication constraints and accelerated design for high-linearity sensors, AIP Publishing LLC, available at: https://doi.org/10.1063/5.0299387 [Accessed 27 Jun. 2026].

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Título: Automated multiphysics MEMS co-optimization platform: Integrated fabrication constraints and accelerated design for high-linearity sensors

Autor / colaboradores: Peizhi Yu et al

Editorial: AIP Publishing LLC

Año de publicación: 2026

ISSN: 1672-6030

ISSN: 1672-6030

Idioma: eng