TY - GEN
T1 - Study of a Voltage-Mode Readout Configuration for Micromachined CMOS Transistors for Uncooled IR Sensing
AU - Moisello, Elisabetta
AU - Vaiana, Michele
AU - Castagna, Maria Eloisa
AU - Bruno, Giuseppe
AU - Bronk, Igor
AU - Blank, Tanya
AU - Bar-Lev, Sharon
AU - Nemirovsky, Yael
AU - Malcovati, Piero
AU - Bonizzoni, Edoardo
N1 - Publisher Copyright:
© 2021 IEEE.
PY - 2021/2/21
Y1 - 2021/2/21
N2 - Micromachined CMOS transistors, dubbed as 'TMOS', have been developed in recent years as a novel type of uncooled thermal sensors. The TMOS consists of a thermally isolated suspended transistor, fabricated in a 130-nm process and released by dry etching, which absorbs thermal radiation, inducing an increase of the transistor temperature and, therefore, generating a signal by changing the transistor I-V characteristics. With respect to conventional thermal sensors, as the TMOS is an active sensing element, it features advantages in terms of internal gain, resulting in high temperature sensitivity, which makes the TMOS particularly appealing. The TMOS sensing performance depends on the transistor operating region and on its configuration. In this paper, different configurations are investigated by means of Cadence simulations, in order to identify the voltage-mode readout configuration which maximizes the sensor performance. Voltage-mode, and not current-mode, readout is considered in order to be able to directly compare the TMOS performance with the one of an integrated micromachined thermopile sensor, which, given its characteristics, only supports voltage-mode readout.
AB - Micromachined CMOS transistors, dubbed as 'TMOS', have been developed in recent years as a novel type of uncooled thermal sensors. The TMOS consists of a thermally isolated suspended transistor, fabricated in a 130-nm process and released by dry etching, which absorbs thermal radiation, inducing an increase of the transistor temperature and, therefore, generating a signal by changing the transistor I-V characteristics. With respect to conventional thermal sensors, as the TMOS is an active sensing element, it features advantages in terms of internal gain, resulting in high temperature sensitivity, which makes the TMOS particularly appealing. The TMOS sensing performance depends on the transistor operating region and on its configuration. In this paper, different configurations are investigated by means of Cadence simulations, in order to identify the voltage-mode readout configuration which maximizes the sensor performance. Voltage-mode, and not current-mode, readout is considered in order to be able to directly compare the TMOS performance with the one of an integrated micromachined thermopile sensor, which, given its characteristics, only supports voltage-mode readout.
UR - https://www.scopus.com/pages/publications/85100604618
U2 - 10.1109/LASCAS51355.2021.9459117
DO - 10.1109/LASCAS51355.2021.9459117
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AN - SCOPUS:85100604618
T3 - 2021 IEEE 12th Latin American Symposium on Circuits and Systems, LASCAS 2021
BT - 2021 IEEE 12th Latin American Symposium on Circuits and Systems, LASCAS 2021
T2 - 12th IEEE Latin American Symposium on Circuits and Systems, LASCAS 2021
Y2 - 22 February 2021 through 25 February 2021
ER -