A 5GS/s 360MHz-BW 68dB-DR Continuous-Time 1-1-1 Filtering MASH ΔΣ ADC in 40nm CMOS

2022 IEEE International Solid- State Circuits Conference (ISSCC) Pub Date : 2022-02-20 DOI:10.1109/ISSCC42614.2022.9731789

Qilong Liu, L. Breems, Chenming Zhang, Shagun Bajoria, M. Bolatkale, R. Rutten, G. Radulov

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引用次数: 1

Abstract

In the pursuit of ever larger bandwidths, in recent years GHz-rate continuous-time (CT) oversampled ADCs have been reported in literature that achieve bandwidths of hundreds of MHz and have even exceeded the GHz barrier [1]–[3]. As impressive as these bandwidths are for CT ADCs, the required ADC architectures are complex, are sensitive to layout parasitics due to the high sampling rates, and most important of all, are power hungry, consuming several hundreds of mW. In this paper, we propose a filtering rnulti-stage noise-shaping (MASH) ΔΣ ADC architecture that overcomes the abovementioned drawbacks. Passive delay compensating filters [4] are used to realize broadband and deep suppression of the input signal component at the internal filter nodes of the ADC. As a result, no interstage DACs are needed, which are commonly required to generate the quantization error replicas in a MASH ΔΣ ADC, saving substantial power and greatly reducing the parasitic load of the high-speed critical nodes. Moreover, because of the absence of signal content at the internal filter nodes, the backend stages of the MASH architecture have relaxed linearity requirements and can be implemented with simple low-power Gm-C filters. Precise excess loop delay and excess phase compensation are accomplished with a partly resistive and capacitive stabilization DAC, enabling very-high-speed operation of the ΔΣ loops. The realized MASH ADC is sampled at 5GHz and achieves 68dB/65dB DR/peak SNDR over a 360MHz bandwidth, -78dBc THD at -1dBFS for a 115MHz input signal, and consumes 158mW. Implemented in a mature 40nm CMOS technology, the ADC occupies only 0.21 mm2 core area, achieves 2× lower power, 5dB higher Schreier FOM and 2× lower Walden FOM compared to state-of-the-art broadband CT ADCs in advanced 16nm-28nm nodes [1]–[3].

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5GS/s 360MHz-BW 68dB-DR连续时间1-1-1滤波MASH ΔΣ 40nm CMOS ADC

为了追求更大的带宽，近年来已有文献报道了GHz速率连续时间(CT)过采样adc实现数百MHz的带宽，甚至超过了GHz屏障[1]-[3]。尽管这些带宽对于CT ADC来说令人印象深刻，但所需的ADC架构很复杂，由于高采样率而对布局寄生很敏感，最重要的是，功耗很高，消耗数百兆瓦。在本文中，我们提出了一种滤波零级噪声整形(MASH) ΔΣ ADC架构，克服了上述缺点。无源延迟补偿滤波器[4]用于在ADC的内部滤波器节点上实现对输入信号分量的宽带和深度抑制。因此，不需要在MASH ΔΣ ADC中生成量化误差副本通常需要的级间dac，从而节省了大量功率并大大降低了高速关键节点的寄生负载。此外，由于内部滤波器节点没有信号内容，MASH架构的后端对线性度的要求较低，可以用简单的低功耗Gm-C滤波器实现。精确的过量环路延迟和过量相位补偿是通过部分电阻和电容稳定DAC实现的，从而实现ΔΣ环路的高速运行。所实现的MASH ADC在5GHz采样，在360MHz带宽下实现68dB/65dB DR/峰值SNDR，在115MHz输入信号下，在-1dBFS下实现-78dBc THD，功耗158mW。该ADC采用成熟的40nm CMOS技术，与先进的16nm-28nm节点[1]-[3]的最先进宽带CT ADC相比，其核心面积仅为0.21 mm2，功耗低2倍，Schreier FOM高5dB, Walden FOM低2倍。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE International Solid- State Circuits Conference (ISSCC)

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