Low-Noise Chopper-Stabilized Zero-Drift Amplifier With SAR-Assisted Automatic Offset Calibration Loop

This paper presents a low-noise chopper-stabilized zero-drift amplifier with successive approximation register (SAR)-assisted automatic offset calibration loop (AOCL). The amplifier is designed using multipath zero-drift architecture including a low frequency path (LFP) and a high frequency path (HF...

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Bibliographic Details
Published in:IEEE access 2023, Vol.11, p.137688-137701
Main Authors: Nam, Gibae, Choi, Gyuri, Yoo, Mookyoung, Kang, Sanggyun, Jin, Byeongkwan, Son, Hyeoktae, Kim, Kyounghwan, Wi, Jihyang, Ahn, Seungmin, Ko, Hyoungho
Format: Article
Language:English
Subjects:
Amplification
Amplifier design
Amplifiers
automatic offset calibration loop (AOCL)
Bandwidth
Calibration
Capacitors
Choppers (circuits)
Digital to analog converters
Drift
High frequency
LF noise
Low noise
Low-frequency noise
Multipath amplifier
Power efficiency
Resistors
ripple reduction
Ripples
SAR
Thermal noise
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Summary:This paper presents a low-noise chopper-stabilized zero-drift amplifier with successive approximation register (SAR)-assisted automatic offset calibration loop (AOCL). The amplifier is designed using multipath zero-drift architecture including a low frequency path (LFP) and a high frequency path (HFP). The multipath architecture can achieve the low offset, the low noise and the low drift while maintaining the wide bandwidth. The LFP amplifier exploits a chopper scheme to reduce the offset and the low-frequency noise components. The digitally assisted AOCLs in the LFP and the HFP using SAR and current-mode digital-to-analog converter (DAC) can reduce the offset coarsely. The mismatch and the offset of the LFP amplifier can generate the up-modulated output ripples. The residual ripples in the LFP can be reduced using a ripple reduction loop (RRL). To prevent secondary ripple caused by the offset of the RRL itself, an auto-zero (AZ) integrator is employed. The HFP amplifier is designed using the folded-cascode structure with class-AB output stage to enhance the power efficiency. The multipath amplifier is fabricated in a 0.18 ~\mu \text{m} CMOS process. The current consumption, supply voltage and active area are 130 ~\mu \text{A} , 1.8 V and 0.86 mm2, respectively. The amplifier has a unit gain bandwidth (UGBW) of 0.875 MHz, an input referred offset of 4.6 ~\mu \text{V} , an input referred noise of 25.6 nV/ \surd Hz, an offset drift of 53 nV/°C and a noise efficiency factor (NEF) of 11.2.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2023.3340427