A 91.0-dB SFDR Single-Coarse Dual-Fine Pipelined-SAR ADC With Split-Based Background Calibration in 28-nm CMOS

This paper presents a single-coarse dual-fine architecture that improves energy-efficiency of pipelined-SAR analog-to-digital converters (ADCs). A coarse and fast sub-ADC is used to quantize the most significant bits (MSBs), which are encoded with a proposed residue transformation method to control the residue generation of the first stages in two fine channels. The residue voltages generate on the capacitive digital-to-analog converters (C-DACs) of split fine channels directly without successive approximation processes. Therefore, the conversion rate is increased and the power is reduced. A shuffle mechanism is introduced into split-ADC based digital background calibration to avoid the divergence of the conventional algorithm in the proposed architecture. A high-energy-efficiency dynamic amplifier is also introduced as the residue amplifier. A 14-bit 60-MS/s ADC is prototyped in a 28-nm CMOS process. The digital calibration engine operates under 0.9-V supply, other parts of the ADC core operate under 1.05-V supply. The ADC core consumes 4.26 mW. Measurement results show that the calibration improved the signal-to-noise and distortion ratio (SNDR) and spur-free dynamic range (SFDR) dramatically, the calibrated ADC achieves SNDR and SFDR of 66.9 dB and of 91.0 dB respectively, translating to a Schreier FoM of 165.4 dB and a Walden FoM of 39.3 fJ/conversion-step.

Automated summary

This paper introduces a single-coarse dual-fine ADC architecture to enhance energy-efficiency by optimizing quantization and residue generation processes. The proposed digital background calibration and dynamic amplifier further improve performance, leading to significant enhancements in signal-to-noise ratio and distortion characteristics in measurement.