Title :
A 0.8-V 48μW 82dB SNDR 10-kHz bandwidth ΣΔ modulator
Author :
Wei Lang ; Peiyuan Wan ; Pingfen Lin
Author_Institution :
Beijing Univ. of Technol., Beijing, China
Abstract :
This paper presents a low-power chopper stabilized discrete-time 2nd-order feed-forward ΣΔ modulator with a 4-bit asynchronous successive approximation register (SAR) quantizer. The weighted sum of integrated and feed-forward signals is merged with the sampling phase of the SAR quantizer to minimize the distortion sources and associated hardware overhead. The 1st integrator uses a partially switched operational amplifier biased in weak inversion to reduce power consumption. The 4-bit SAR quantizer further employs an asynchronous control scheme to reduce the loop delay and power consumption. A 0.13-μm CMOS experimental prototype achieves 84dB dynamic range, 84dB peak SNR, and 82dB peak SNDR over an input bandwidth of 10-kHz. The total power consumption of the modulator is 48μW from a 0.8-V supply at an 800-kHz sampling rate.
Keywords :
CMOS integrated circuits; choppers (circuits); distortion; feedforward; low-power electronics; operational amplifiers; quantisation (signal); shift registers; sigma-delta modulation; CMOS process; SAR quantizer; SNDR; associated hardware overhead; asynchronous control scheme; asynchronous successive approximation register quantizer; bandwidth 10 kHz; distortion source minimization; feedforward signals; first integrator; frequency 800 kHz; loop delay; low-power chopper stabilized discrete-time 2nd-order feed-forward ΣΔ modulator; partially switched operational amplifier; power 48 muW; sampling phase; size 0.13 mum; voltage 0.8 V; word length 4 bit; CMOS integrated circuits; Capacitors; Delay; Modulation; Power demand; Switches; Topology; Analog-digital conversion; Sigma delta modulator; asynchronous circuits; successive approximation register; switched capacitor circuits;
Conference_Titel :
Radio-Frequency Integration Technology (RFIT), 2012 IEEE International Symposium on
Conference_Location :
Singapore
Print_ISBN :
978-1-4673-2303-1
DOI :
10.1109/RFIT.2012.6401623
