Low Power SAR ADC Design with Digital Background Calibration Algorithm

This paper proposed a digital background calibration algorithm with positive and negative symmetry error tolerance to remedy the capacitor mismatch for successive approximation register analog-to-digital converters (SAR ADCs). Compensate for the errors caused by capacitor mismatches and improve the ADC performance. Combination with a tri-level switching scheme based on the common-mode voltage Vcm to achieve capacitor reduction and high switching energy efficiency. The proposed calibration algorithm significantly improves capacitor mismatch without resorting to extensive computation or dedicated circuits. The active area is 0.046 mm2 in 40 nm Complementary Metal-Oxide-Semiconductor (CMOS) technology. The post-simulation results show the effective number of bits (ENOB) improves from 8.23 bits to 11.36 bits, signal-to-noise-and distortion ratio (SNDR) improves from 51.33 dB to 70.15 dB, respectively, before and after calibration. This improves the spurious-free dynamic range (SFDR) by 24.13 dB, from 61.50 dB up to 85.63 dB. The whole ADC’s power consumption is only 0.3564 mW at sampling rate fs =2 MS/s and Nyquist input frequency, with a figure-of-merit (FOM) 67.8 fJ/conv.-step.

A 6.4-GS/s 10-b Time-Interleaved SAR ADC with Time-Skew Immune Sampling Network in 28-nm CMOS

This paper presents a 6.4-GS/s 16-way 10-bit time-interleaved (TI) SAR ADC for wideband wireless applications. A two-stage master–slave hierarchical sampling network, which is immune to the time skew of multi-phase clocks, is introduced to avoid the time-skew calibration for design simplicity and hardware efficiency. To perform low distortion and fast sampling at acceptable power consumption, a linearity- and energy efficiency-improved track-and-hold (T&H) buffer with current-feedback compensation scheme is proposed. Accompanied by its low-output-impedance feature, the buffer obtains adequate bandwidth which can cover the entire ADC Nyquist sampling range. Moreover, the split capacitor DAC combined with a novel nonbinary algorithm is adopted in single-channel ADC, enabling a shorter DAC settling time as well as less switching energy. Capacitor mismatch effect with related design trade-off is discussed and behavior models are built to evaluate the effect of capacitor mismatch on ENOB. An asynchronous self-triggered SAR logic is designed and optimized to minimize the delay on logic paths to match up the acceleration on DAC and comparator. With these proposed techniques, the 10-b sub-ADC achieves a 400-MHz conversion rate with only 3.5-mW power consumption. The circuit is designed and simulated in TSMC 28 HPC process and the results show that the overall ADC achieves 54.6-dB SNDR and 58.1-dB SFDR at Nyquist input while consuming 127-mW power from 1-V/1.5-V supply and achieving a Walden FoM of 45[Formula: see text]fJ/conv-step.