Chang Suk Han scite author profile

-This paper presents a parameterized simulation program with integrated circuit emphasis (SPICE) model of a two-level microbolometer based on negative-temperature-coefficient thin films, such as vanadium oxide or amorphous silicon. The proposed modeling begins from the electricthermal analogy and is realized on the SPICE modeling environment. The model consists of parametric components whose parameters are material properties and physical dimensions, and can be used for the fast design study, as well as for the co-design with the readout integrated circuit. The developed model was verified by comparing the obtained results with those from finite element method simulations for three design cases. The thermal conductance and the thermal capacity, key performance parameters of a microbolometer, showed the average difference of only 4.77% and 8.65%, respectively.

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SPICE-Compatible Modeling of a Microbolometer Package Including Thermoelectric Cooler

Han

Park²,

Kim³

et al. 2013

Journal of Sensor Science and Technology

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For a successful commercialization of microbolometer, it is required to develop a robust package including thermal stabilizing mechanism. In order to regulate the temperature within some operating range, thermoelectric cooler is generally used but it's not easy to model the whole package due to the coupled physics nature of thermoelectric cooler. In this paper, SPICE-compatible modeling methodology of a microbolometer package is presented, whose steady-state results matched well with FEM results at the maximum difference of 5.95%. Although the time constant difference was considerable as 15.7%, it can be offset by the quite short simulation time compared to FEM simulation. The developed model was also proven to be useful for designing the thermal stabilizer through parametric and transient analyses under the various working conditions. Keywords : Microbolometer, Thermoelectric cooler, MEMS, package, SPICE 1 2 3 + Corresponding author: sohan@hoseo.edu (Received : Oct. 2, 2012, Revised : Nov. 29, 2012, Accepted : Dec. 9, 2012 This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License(http://creativecommons.org/licenses/bync/3.0)which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Microstructure of Carbide Precipitates in L12-Ni3Al and L10-TiAl

Han

2008

Met. Mater. -Int.

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Chang Suk Han

Coupled Physics Analyses of VOx-Based, Three-Level Microbolometer

RETRACTED ARTICLE: Dislocation-particle interaction in precipitation strengthened Ll2-ordered Ni3Al

Parameterized Simulation Program with Integrated Circuit Emphasis Modeling of Two-level Microbolometer

SPICE-Compatible Modeling of a Microbolometer Package Including Thermoelectric Cooler

Microstructure of Carbide Precipitates in L12-Ni3Al and L10-TiAl

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