Author :
Grassi, Marco ; Malcovati, Piero ; Baschirotto, Andrea
Abstract :
In this paper, we present the design and the characterization of a wide-dynamic-range interface circuit for resistive gas-sensors able to operate without calibration. The circuit is based on resistance-to-frequency conversion, which guarantees low complexity. The state-of-the-art of this measurement method has been improved first by separating the resistance value controlled oscillator circuit (RCO) from the sensing device, thus leading to higher linearity performance, and then by exploiting a novel digital frequency measurement system. Measurement results on a silicon prototype, designed in a 0.35-mum CMOS technology, show that the circuit achieves, without calibration, a precision in resistance measurement of 0.4% over a range of 4 decades and better than 0.8% over 5 decades (dynamic range, DR = 141 dB). Furthermore, after calibration, it reaches a precision of 0.4% for resistance values ranging between 1 kOmega and 1 GOmega, thus leading to a DR of 168 dB. The prototype chip consumes less than 15 mW from a 3.3-V supply.
Keywords :
CMOS integrated circuits; frequency measurement; gas sensors; integrated circuit design; mixed analogue-digital integrated circuits; oscillators; pattern recognition; CMOS gas-sensor; CMOS technology; digital frequency measurement system; dynamic range interface circuit; mixed analog-digital IC; pattern recognition system; resistance 1 kohm to 1 Gohm; resistance value controlled oscillator circuit; resistance-to-frequency conversion; resistive gas-sensors; silicon prototype; size 0.35 mum; voltage 3.3 V; word length 16 bit; CMOS digital integrated circuits; CMOS technology; Calibration; Control systems; Dynamic range; Electrical resistance measurement; Frequency measurement; Linearity; Oscillators; Prototypes; Gas-sensor interface circuit; mixed analog-digital IC; resistance-to-frequency conversion;
