Successive Approximation Register Analog-to-Digital Converter (SAR ADC) for Biomedical Applications

IF 1.3 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Active and Passive Electronic Components Pub Date : 2023-01-04 DOI:10.1155/2023/3669255

Kawther I. Arafa, Dina M. Ellaithy, A. Zekry, M. Abouelatta, H. Shawkey

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引用次数: 3

Abstract

This study presents a survey of the most promising reported SAR ADC designs for biomedical applications, stressing advantages, disadvantages, and limitations, and concludes with a quantitative comparison. Recent progress in the development of a single SAR ADC architecture is reviewed. In wearable and biosensor systems, a very small amount of total power must be devoured by portable batteries or energy-harvesting circuits in order to function correctly. During the past decade, implementation of the high energy efficiency of SAR ADC has become the most necessary. So, several different implementation schemes for the main components of the SAR ADC have been proposed. In this review study, the various circuit architectures have been explained, beginning with the sample and hold (S/H) switching circuits, the dynamic comparator, the internal digital-to-analog converter (DAC), and the SAR control logic. In order to achieve low power consumption, numerous different configurations of dynamic comparator circuits are revealed. At the end of this overview, the evolutions of DAC architecture in distinct biomedical applications today can make a tradeoff between resolution, speed, and linearity, which represent the challenges of a single SAR ADC. For high resolution, the dual split capacitive DAC (CDAC) array technique and hybrid capacitor technique can be used. Also, for ultralow power consumption, various voltage switching schemes are achieved to reduce the number of switches. These schemes can save switching energy and reduce capacitor array area with high linearity. Additionally, to increase the speed of the conversion process, a prediction-based ADC design is employed. Therefore, SAR ADC is considered the ideal solution for biomedical applications.

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生物医学应用的逐次逼近寄存器模数转换器(SAR ADC)

本研究介绍了生物医学应用中最有前途的SAR ADC设计，强调了优点、缺点和局限性，并以定量比较结束。综述了单一SAR ADC体系结构的最新进展。在可穿戴和生物传感器系统中，为了正常工作，便携式电池或能量收集电路必须消耗非常少量的总功率。在过去的十年中，实现SAR ADC的高能效已成为当务之急。因此，针对SAR ADC的主要组件提出了几种不同的实现方案。在本综述研究中，已经解释了各种电路架构，从采样和保持(S/H)开关电路，动态比较器，内部数模转换器(DAC)和SAR控制逻辑开始。为了实现低功耗，动态比较器电路的许多不同配置被揭示出来。在本综述的最后，DAC架构在当今不同生物医学应用中的发展可以在分辨率、速度和线性度之间进行权衡，这代表了单个SAR ADC的挑战。为了获得高分辨率，可以采用双分路电容式DAC (CDAC)阵列技术和混合电容技术。此外，为了超低功耗，实现了各种电压开关方案，以减少开关数量。这些方案可以节省开关能量，减小电容阵列面积，线性度高。此外，为了提高转换过程的速度，采用了基于预测的ADC设计。因此，SAR ADC被认为是生物医学应用的理想解决方案。

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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来源期刊

Active and Passive Electronic Components ENGINEERING, ELECTRICAL & ELECTRONIC-

CiteScore

1.30

自引率

0.00%

发文量

审稿时长

13 weeks

期刊介绍： Active and Passive Electronic Components is an international journal devoted to the science and technology of all types of electronic components. The journal publishes experimental and theoretical papers on topics such as transistors, hybrid circuits, integrated circuits, MicroElectroMechanical Systems (MEMS), sensors, high frequency devices and circuits, power devices and circuits, non-volatile memory technologies such as ferroelectric and phase transition memories, and nano electronics devices and circuits.

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