A K-Delta-1-Sigma modulator for wideband analog to digital conversion

2009 52nd IEEE International Midwest Symposium on Circuits and Systems Pub Date : 2009-09-15 DOI:10.1109/MWSCAS.2009.5236069

V. Saxena, Kaijun Li, Geng Zheng, R. J. Baker

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引用次数: 11

Abstract

As CMOS technology shrinks, the transistor speed increases enabling higher speed communications and more complex systems. These benefits come at the cost of decreasing inherent device gain, increased transistor leakage currents, and additional mismatches due to process variations. All of these drawbacks affect the design of high-resolution analog-to-digital converters (ADCs) in nano-CMOS processes. To move towards an ADC topology useful in these small processes the K-Delta-1- Sigma (KD1S) modulator-based ADC was proposed. The KD1S topology employs inherent time-interleaving with a shared opamp and K-quantizing paths and can achieve significantly higher conversion bandwidths when compared to the traditional delta-sigma ADCs. The 8-path KD1S modulator achieves an SNR of 58 dB (or 9.4-bits resolution) when clocked at 100 MHz for a conversion bandwidth of 6.25 MHz and an effective sampling rate equal to 800 MHz. The KD1S modulator has been fabricated in a 500 nm CMOS process and the experimental results are reported. Deficiencies in the first test chip performance are discussed along with their alleviation to achieve theoretical performance.

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用于宽带模拟数字转换的K-Delta-1-Sigma调制器

随着CMOS技术的缩小，晶体管的速度增加，从而实现更高速度的通信和更复杂的系统。这些好处的代价是降低固有器件增益，增加晶体管漏电流，以及由于工艺变化而导致的额外不匹配。这些缺点都影响了纳米cmos工艺中高分辨率模数转换器(adc)的设计。为了实现对这些小过程有用的ADC拓扑结构，提出了基于K-Delta-1- Sigma (KD1S)调制器的ADC。KD1S拓扑采用固有的时间交错，具有共享的运放和k量化路径，与传统的δ - σ adc相比，可以实现更高的转换带宽。当时钟频率为100 MHz，转换带宽为6.25 MHz，有效采样率为800 MHz时，8路KD1S调制器的信噪比为58 dB(或9.4位分辨率)。采用500 nm CMOS工艺制备了KD1S调制器，并报道了实验结果。讨论了首次测试芯片性能的不足，并对其进行了改进，以达到理论性能。

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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2009 52nd IEEE International Midwest Symposium on Circuits and Systems

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