A 23.7‐uW 93.5‐dB SNDR delta‐sigma modulator for healthcare and medical diagnostics

This paper presents a high‐precision, low‐power delta‐sigma modulator (DSM) designed for healthcare and medical diagnostics. It utilizes a hybrid switching integrator to reduce distortion caused by the non‐linear on‐resistance of switches at a low supply voltage. Leveraging the characteristics of the hybrid switching integrator, a non‐50% duty cycle sampling timing and a corresponding tunable Miller‐compensated operational transconductance amplifier are proposed to reduce resistor thermal noise and meet lower power consumption requirements. The DSM is simulated based on 130‐nm CMOS technology and achieves 93.5‐dB signal‐to‐noise‐plus‐distortion ratio at a 1‐kHz bandwidth while consuming 23.7 µW from a 1.5‐V supply. This paper presents a high‐precision, low‐power delta‐sigma modulator (DSM) designed for healthcare and medical diagnostics. It utilizes a hybrid switching integrator to reduce distortion caused by the non‐linear on‐resistance of switches at a low supply voltage. Leveraging the characteristics of the hybrid switching integrator, a non‐50% duty cycle sampling timing and a corresponding tunable Miller‐compensated operational transconductance amplifier are proposed to reduce resistor thermal noise and meet lower power consumption requirements. The DSM is simulated based on 130‐nm CMOS technology and achieves 93.5‐dB signal‐to‐noise‐plus‐distortion ratio at a 1‐kHz bandwidth while consuming 23.7 μW from a 1.5‐V supply.