TY - GEN
T1 - 9.7 A 94.3dB SNDR 184dB FoMs 4th-Order Noise-Shaping SAR ADC with Dynamic-Amplifier-Assisted Cascaded Integrator
AU - Cheng, Kai Cheng
AU - Chang, Soon Jyh
AU - Chen, Chung Chieh
AU - Hung, Shuo Hong
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - The noise-shaping (NS) SAR ADC, which features the advantages of sigma-delta ADCs and SAR ADCs, is high accuracy and low power, so it stands out as a great choice for audio applications of IoT devices. Attaining high-performance and high-yield in an NS-SAR ADC is challenging due to the requirements of meeting a high-order noise transfer function (NTF), power efficiency, and robustness across PVT variations at the same time. The error-feedback (EF) structure implements FIR filters with multi-cycle delays [1], which simplifies implementation but makes NTF coefficients sensitive to gain variation. Therefore, foreground trimming is necessary for precise amplifier gains. The cascaded-integrator-feedforward (CIFF) structure [2-5] implements cascaded integrators to realize NTF, whose coefficients are less sensitive to variation. Closed-loop amplifier-based integration can achieve a nearly perfect NTF, but the high-gain amplifier with multiple stages may introduce extra noise or large power consumption [2]. Passive charge-sharing integration is implemented to reduce power consumption, but it leads to a mild NTF and requires larger capacitors for noise suppression. Capacitor-stacking with dynamic buffers/amps can be used to achieve a nearly perfect NTF [3-4], but it requires N buffers/amps to implement an Nth-order NS, making it less power efficient.
AB - The noise-shaping (NS) SAR ADC, which features the advantages of sigma-delta ADCs and SAR ADCs, is high accuracy and low power, so it stands out as a great choice for audio applications of IoT devices. Attaining high-performance and high-yield in an NS-SAR ADC is challenging due to the requirements of meeting a high-order noise transfer function (NTF), power efficiency, and robustness across PVT variations at the same time. The error-feedback (EF) structure implements FIR filters with multi-cycle delays [1], which simplifies implementation but makes NTF coefficients sensitive to gain variation. Therefore, foreground trimming is necessary for precise amplifier gains. The cascaded-integrator-feedforward (CIFF) structure [2-5] implements cascaded integrators to realize NTF, whose coefficients are less sensitive to variation. Closed-loop amplifier-based integration can achieve a nearly perfect NTF, but the high-gain amplifier with multiple stages may introduce extra noise or large power consumption [2]. Passive charge-sharing integration is implemented to reduce power consumption, but it leads to a mild NTF and requires larger capacitors for noise suppression. Capacitor-stacking with dynamic buffers/amps can be used to achieve a nearly perfect NTF [3-4], but it requires N buffers/amps to implement an Nth-order NS, making it less power efficient.
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U2 - 10.1109/ISSCC49657.2024.10454362
DO - 10.1109/ISSCC49657.2024.10454362
M3 - Conference contribution
AN - SCOPUS:85188127085
T3 - Digest of Technical Papers - IEEE International Solid-State Circuits Conference
SP - 180
EP - 182
BT - 2024 IEEE International Solid-State Circuits Conference, ISSCC 2024
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2024 IEEE International Solid-State Circuits Conference, ISSCC 2024
Y2 - 18 February 2024 through 22 February 2024
ER -