20.4 An 8 × - OSR 25MHz-BW 79.4dB/74dB DR/SNDR CT Δ σ Modulator Using 7b Linearized Segmented DACs with Digital Noise-Coupling-Compensation Filter in 7nm FinFET CMOS

• Published in: 2019 IEEE International Solid- State Circuits Conference - (ISSCC) pp. 334 - 336
• Main Authors: Lo, Tien-Yu, Weng, Chan-Hsiang, Hsieh, Hung-Yi, Shu, Yun-Shiang, Chiu, Pao-Cheng
• Format: Conference Proceeding
• Language: English
• Published: IEEE 01.02.2019
• Subjects: Couplings; FinFETs; Modulation; Quantization (signal); Signal to noise ratio; Switches
• ISSN: 2376-8606
• DOI: 10.1109/ISSCC.2019.8662371

A low-power and high-dynamic-range downlink ADC is the most critical building block in a cellular receiver design. A continuous-time delta-sigma modulator (CTDSM), which gets the benefit of inherent anti-alias filtering, is a common architecture choice for the ADC. However, low power dissipation dictates a low over-sampling ratio (OSR) since the bandwidth of the loop filter, DAC switching rate, and the clock frequency of the subsequent digital front-end are all proportional to the sampling frequency. Due to the desire for low OSR, a higher quantization level is required to maintain dynamic range, and the successive approximation register (SAR) quantizer, which gets the benefits of power and area efficiency compared to a flash quantizer, becomes more attractive in nanometer processes. However, the issue with a SAR quantizer in a high-speed CTDSM is the limited signal processing time available to achieve lower quantization noise and feedback DAC linearization. In this work, a 12 cycle, 400MHz passive noise-shaping SAR (NS-SAR) is embedded in a low-OSR CTDSM to fulfill the link budget requirement. Two techniques to satisfy the requirement of shorter signal processing time to DAC feedback path are introduced: segmented mismatch error shaping (S-MES) to achieve linear segmented DACs and digital noise coupling compensation filtering (DNCCF) to achieve low quantization noise.