An Energy-Efficient Capacitively Biased Diode-Based Temperature Sensor in 55-nm CMOS
Zhong Tang, Yun Fang, Xiaopeng Yu, Nick Nianxiong Tan, Zheng Shi, Pieter Harpe
Abstract
This work presents an energy-efficient diode-based CMOS temperature sensor. It is based on the capacitively-biased diode (CBD) working principle and can operate with a 1-V supply voltage. Instead of using a separate CBD front-end and ADC, a new architecture is proposed in which the CBD front-end is directly embedded into the 1st stage of a 1-bit 2nd-order switched-capacitor Σ-ADC, thereby improving both energy efficiency and accuracy. The circuit was fabricated in a standard 55-nm CMOS process and occupies an active area of 0.021 mm. The measured inaccuracy is ±0.6∘C (3σ) from -55 to 125 ∘C after a 1-point calibration. Furthermore, it consumes 2.2 W and achieves a resolution of 15 mK in a conversion time of 6.4 ms, which corresponds to a competitive resolution FoM of 3.2 pJ∙K.