Core model for independent multigate MOSFETs

Juan Pablo Duarte; Sourabh Khandelwal; Huan Lin Chang; Yen Kai Lin; Pragya Kushwaha; Yogesh Singh Chauhan; Chenming Hu

doi:10.1016/B978-0-08-102401-0.00002-9

Core model for independent multigate MOSFETs

Juan Pablo Duarte, Sourabh Khandelwal, Huan Lin Chang, Yen Kai Lin, Pragya Kushwaha, Yogesh Singh Chauhan, Chenming Hu

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

This chapter presents the core model for the industry standard compact model BSIM-IMG, a fully featured turn-key compact model for independent multigate MOSFETs. The two independent (front and back gates) controls of the channel charge in these devices enable novel applications wherein the back gate can be in depletion or inversion, and BSIM-IMG accurately models these scenarios. Modeling of the channel charge in this device requires a consistent solution of coupled Poisson’s equations at the front and the back gate. This chapter presents an analytical solution for the Poisson’s equation which is numerically robust and passes important quality tests for an industry grade compact model. To represent real device effects, several extra models are later incorporated, such as drain-induced barrier lowering, velocity saturation, short-channel effects, self-heating effect, mobility-field dependence, and substrate-depletion effect.

Original language	English
Title of host publication	Industry Standard FDSOI Compact Model BSIM-IMG for IC Design
Publisher	Elsevier
Pages	15-34
Number of pages	20
ISBN (Electronic)	9780081024010
ISBN (Print)	9780081024027
DOIs	https://doi.org/10.1016/B978-0-08-102401-0.00002-9
State	Published - 1 Jan 2019

Keywords

BSIM-IMG
Back gate
Front gate
MOSFETs
Multigate
Poisson

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10.1016/B978-0-08-102401-0.00002-9

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title = "Core model for independent multigate MOSFETs",

abstract = "This chapter presents the core model for the industry standard compact model BSIM-IMG, a fully featured turn-key compact model for independent multigate MOSFETs. The two independent (front and back gates) controls of the channel charge in these devices enable novel applications wherein the back gate can be in depletion or inversion, and BSIM-IMG accurately models these scenarios. Modeling of the channel charge in this device requires a consistent solution of coupled Poisson{\textquoteright}s equations at the front and the back gate. This chapter presents an analytical solution for the Poisson{\textquoteright}s equation which is numerically robust and passes important quality tests for an industry grade compact model. To represent real device effects, several extra models are later incorporated, such as drain-induced barrier lowering, velocity saturation, short-channel effects, self-heating effect, mobility-field dependence, and substrate-depletion effect.",

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author = "Duarte, {Juan Pablo} and Sourabh Khandelwal and Chang, {Huan Lin} and Lin, {Yen Kai} and Pragya Kushwaha and Chauhan, {Yogesh Singh} and Chenming Hu",

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AU - Duarte, Juan Pablo

AU - Khandelwal, Sourabh

AU - Chang, Huan Lin

AU - Lin, Yen Kai

AU - Kushwaha, Pragya

AU - Chauhan, Yogesh Singh

AU - Hu, Chenming

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AB - This chapter presents the core model for the industry standard compact model BSIM-IMG, a fully featured turn-key compact model for independent multigate MOSFETs. The two independent (front and back gates) controls of the channel charge in these devices enable novel applications wherein the back gate can be in depletion or inversion, and BSIM-IMG accurately models these scenarios. Modeling of the channel charge in this device requires a consistent solution of coupled Poisson’s equations at the front and the back gate. This chapter presents an analytical solution for the Poisson’s equation which is numerically robust and passes important quality tests for an industry grade compact model. To represent real device effects, several extra models are later incorporated, such as drain-induced barrier lowering, velocity saturation, short-channel effects, self-heating effect, mobility-field dependence, and substrate-depletion effect.

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KW - Front gate

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BT - Industry Standard FDSOI Compact Model BSIM-IMG for IC Design

PB - Elsevier

ER -

Core model for independent multigate MOSFETs

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Keywords

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