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Analysis and Compensation of Stress Effects on CMOS Reference Current Sources

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Titel: Analysis and Compensation of Stress Effects on CMOS Reference Current Sources
Autoren: Barić, Adrijan, Žamboki, Andro, Mikulić, Josip, Gočan, Leo, Marković, Tomislav
Verlagsinformationen: 2023.
Publikationsjahr: 2023
Schlagwörter: MOSFET model, stress, stress compensation, SPICE simulation, encapsulation, reference source
Beschreibung: This paper carries out a thorough analysis of the stress-induced effects on a 180-nm temperature-invariant CMOS reference current source using the previously designed stress-dependent MOSFET and resistor models in the simulations. The encapsulation of chips is often made from polymers (such as epoxy) which are poured over the silicon chips. When the encapsulation cools down, it generates a significant amount of static mechanical stress in the ICs, which changes their performance. Critical parts of the reference current source circuit that are most sensitive to stress are identified and a compensation method is presented. The simulations show that the presented compensation method significantly lowers the sensitivity of the reference current to stress.
Publikationsart: Conference object
Dokumentencode: edsair.dris...01492..ca4d07894953f34dce3251417872c398
Datenbank: OpenAIRE
Beschreibung
Abstract:This paper carries out a thorough analysis of the stress-induced effects on a 180-nm temperature-invariant CMOS reference current source using the previously designed stress-dependent MOSFET and resistor models in the simulations. The encapsulation of chips is often made from polymers (such as epoxy) which are poured over the silicon chips. When the encapsulation cools down, it generates a significant amount of static mechanical stress in the ICs, which changes their performance. Critical parts of the reference current source circuit that are most sensitive to stress are identified and a compensation method is presented. The simulations show that the presented compensation method significantly lowers the sensitivity of the reference current to stress.