This paper demonstrates, via a novel compact model and experiments, that squegging in micromechanical resonant electrical switches (resoswitches) [1] is controllable via impact electrode design. The model captures the nonlinear dynamics of impact contact and predicts squegging. Unlike other numeric and finite-element (FEM)-based models, this physical parameter-based model has no convergence difficulties when simulating impact, accurately captures squegging, and runs within any circuit simulator with up to 100× simulation time improvement compared to commercial software. Matching of compact model simulations to measurements of a 1-kHz RF-powered micromechanical clock receiver [2] validate the model. Proper electrode design yields a 10× reduction in output jitter.
Abstract:
Publication date:
January 24, 2024
Publication type:
Conference Paper (Proceedings)
Citation:
K. H. Zheng, Q. Jin and C. T. . -C. Nguyen, "Resoswitch Squegging Control by Compact Model-Assisted Impact Electrode Design," 2024 IEEE 37th International Conference on Micro Electro Mechanical Systems (MEMS), Austin, TX, USA, 2024, pp. 1071-1074, doi: 10.1109/MEMS58180.2024.10439518. keywords: {Electrodes;Computational modeling;Receivers;Software;Numerical models;Integrated circuit modeling;Clocks;Resoswitch;compact model;Verilog-A;squegging;mechanical receiver},
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