This paper presents a low power temperature compensated CMOS ring oscillator for biomedical applications across a wide temperature range. The proposed circuit deploys an IPTAT (inversely proportional to absolute temperature) bias current by generating an adaptive control voltage in each stage of the oscillator to compensate the overall oscillator’s temperature coefficient (TC). Simulations using TSMC 0.18[Formula: see text][Formula: see text]m CMOS technology show that this configuration can achieve a frequency variation less than 0.25%, leading to an average frequency drift of 20.83[Formula: see text]ppm/∘C. Monte Carlo simulations have also been performed and demonstrate a 3[Formula: see text] deviation of about 2.15%. The power dissipated by the proposed circuit is only 8.48[Formula: see text]mW at 25∘C.
Techniques for low-power CMOS transmitter system integration for short-range radio-frequency communication
