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A 0.058 mm 2 24 μ W Temperature Sensor in 40 nm CMOS Process with ± 0.5 ∘ C Inaccuracy from − 55 to 175 ∘ C

Zhu, Di ; Siek, Liter

Circuits, systems, and signal processing, 2018-06, Vol.37 (6), p.2278-2298 [Periódico revisado por pares]

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Título:
A 0.058 mm 2 24 μ W Temperature Sensor in 40 nm CMOS Process with ± 0.5 ∘ C Inaccuracy from − 55 to 175 ∘ C
Autor: Zhu, Di ; Siek, Liter
Assuntos: Analog circuits ; Circuit design ; CMOS ; Power supplies ; Scaling ; Semiconductor devices ; Sensors ; Substrates ; Temperature ; Temperature sensors ; Transistors ; Zooming
É parte de: Circuits, systems, and signal processing, 2018-06, Vol.37 (6), p.2278-2298
Descrição: This paper describes the design of a high-accuracy smart temperature sensor in the 40 nm standard CMOS process. Due to process scaling, the high threshold voltages, large leakage currents and low intrinsic gains, etc., cause the realization of conventional high performance analog circuits to become very challenging in advanced processes. In the proposed design, some new techniques have been utilized in order to overcome the obstacles due to process scaling. The sensor’s frontend is based on substrate PNP transistors, couple with a two-step zooming ADC. This temperature sensor achieves a two-point calibrated inaccuracy of ±0.5∘C and a one-point trimmed inaccuracy of ±0.8∘C over a range of temperature from − 55 to 175∘C. It draws 20μA from a 1.2 V power supply and occupies an area of 0.0578mm2.
Editor: Cambridge: Springer Nature B.V
Idioma: Inglês

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