Compact RF large-signal model for MEMS capacitive switches

S. Halder; C. Palego; J. Hwant; C.L. Goldsmith

doi:10.1109/MWSYM.2010.5515520

Compact RF large-signal model for MEMS capacitive switches

S. Halder, C. Palego, J. Hwant, C.L. Goldsmith

Research output: Contribution to conference › Paper

Abstract

Last year, we reported on a SPICE-based compact RF small-signal electromechanical model for electrostatically actuated MEMS capacitive shunt switches with movable membranes. We now report on the enhancement of the model to include electrothermal and thermomechanical effects so that the model is applicable under large-signal RF conditions. Specifically, a thermal subcircuit is added to account for the temperature rise in the switch membrane as a function of the dissipated RF power. In turn, the temperature rise is used to evaluate the decrease in the membrane spring constant. These enhancements allow the present multiphysics model to simulate the coupled self-biasing and self-heating effects under RF large signals and to predict the power-handling capacity of MEMS capacitive switches. Additionally, the model has been coded in Verilog, making it portable between different circuit simulation environments.

Original language	English
Pages	421-424
DOIs	https://doi.org/10.1109/MWSYM.2010.5515520
Publication status	Published - 23 May 2010
Event	Microwave Symposium Digest (MTT), 2010 IEEE MTT-S International, Anaheim, USA, 23-28 May 2010 - Duration: 3 Jan 0001 → …

Conference

Conference	Microwave Symposium Digest (MTT), 2010 IEEE MTT-S International, Anaheim, USA, 23-28 May 2010
Period	3/01/01 → …

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10.1109/MWSYM.2010.5515520

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title = "Compact RF large-signal model for MEMS capacitive switches",

abstract = "Last year, we reported on a SPICE-based compact RF small-signal electromechanical model for electrostatically actuated MEMS capacitive shunt switches with movable membranes. We now report on the enhancement of the model to include electrothermal and thermomechanical effects so that the model is applicable under large-signal RF conditions. Specifically, a thermal subcircuit is added to account for the temperature rise in the switch membrane as a function of the dissipated RF power. In turn, the temperature rise is used to evaluate the decrease in the membrane spring constant. These enhancements allow the present multiphysics model to simulate the coupled self-biasing and self-heating effects under RF large signals and to predict the power-handling capacity of MEMS capacitive switches. Additionally, the model has been coded in Verilog, making it portable between different circuit simulation environments.",

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AU - Halder, S.

AU - Palego, C.

AU - Hwant, J.

AU - Goldsmith, C.L.

PY - 2010/5/23

Y1 - 2010/5/23

N2 - Last year, we reported on a SPICE-based compact RF small-signal electromechanical model for electrostatically actuated MEMS capacitive shunt switches with movable membranes. We now report on the enhancement of the model to include electrothermal and thermomechanical effects so that the model is applicable under large-signal RF conditions. Specifically, a thermal subcircuit is added to account for the temperature rise in the switch membrane as a function of the dissipated RF power. In turn, the temperature rise is used to evaluate the decrease in the membrane spring constant. These enhancements allow the present multiphysics model to simulate the coupled self-biasing and self-heating effects under RF large signals and to predict the power-handling capacity of MEMS capacitive switches. Additionally, the model has been coded in Verilog, making it portable between different circuit simulation environments.

AB - Last year, we reported on a SPICE-based compact RF small-signal electromechanical model for electrostatically actuated MEMS capacitive shunt switches with movable membranes. We now report on the enhancement of the model to include electrothermal and thermomechanical effects so that the model is applicable under large-signal RF conditions. Specifically, a thermal subcircuit is added to account for the temperature rise in the switch membrane as a function of the dissipated RF power. In turn, the temperature rise is used to evaluate the decrease in the membrane spring constant. These enhancements allow the present multiphysics model to simulate the coupled self-biasing and self-heating effects under RF large signals and to predict the power-handling capacity of MEMS capacitive switches. Additionally, the model has been coded in Verilog, making it portable between different circuit simulation environments.

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DO - 10.1109/MWSYM.2010.5515520

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T2 - Microwave Symposium Digest (MTT), 2010 IEEE MTT-S International, Anaheim, USA, 23-28 May 2010

Y2 - 3 January 0001

ER -

Compact RF large-signal model for MEMS capacitive switches

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