使用 Gm-C 滤波器 sigma-delta 调制器的皮安培分辨率电流测量电路,用于低功耗纳米孔 DNA 测序

IF 3 3区 计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Pegah Tahani , Mehdi Habibi , Sebastian Magierowski
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引用次数: 0

摘要

新一代 DNA 测序仪使用配备纳米孔的电化学电池阵列,可产生皮安培级电流。由于通道数量多、电流水平低、带宽仅为几千赫兹,在设计这些读出电路时,二维通道内阵列、低噪声、低功耗模数转换器成为首选。以前曾出现过许多不同的 sigma-delta 调制器,用于将纳米孔电流信号转换成数字代码。传统上,这些转换器所需的运算放大器最终会增加每个通道的功耗。本文提出了一种基于 Gm-C 滤波器的新型二阶 sigma-delta 转换器。在该设计中,只使用了一个 4 晶体管 Gm 块,而不是依靠多个运算放大器来实现必要的增益和噪声性能。评估结果表明,虽然输入参考噪声仍与以前的方法接近,但功耗却大大降低。此外,还实现了一个原型,以显示该方法的有效性。在 180 纳米设计中,每个通道的 ENOB 为 12.16 位,10 kHz 带宽下的 RMS 输入参考噪声为 0.2 pA,功耗为 8.27 μW。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Pico-ampere resolution current measurement circuit using Gm-C filter sigma-delta modulator for low-power nanopore DNA sequencing
New generation DNA sequencers use an array of electrochemical cells equipped with nanopores, which produce pico-ampere current levels. Due to the large number of channels, low current levels and bandwidths in the order of a few kHz, in the design of these readout circuits, 2D arrays of in-channel, low noise and low power analog to digital converters are preferred. Previously many different sigma-delta modulators have been presented to convert the nanopore current signal into a digital code. Conventionally, the opamps required in these converters will eventually increase the power dissipation of each channel. In this paper a novel Gm-C filter based second order sigma-delta converter is proposed. In the given design, rather than relying on multiple opamps to achieve the necessary gain and noise performance, only a 4 transistor Gm block is used. Evaluations show that while the input referred noise remains close to previous methods, the power dissipation is considerably reduced. A prototype is also implemented to show the effectiveness of the approach. In a 180-nm design, an ENOB of 12.16 bits, RMS input referred noise of 0.2 pA at 10 kHz bandwidth and power dissipation of 8.27 μW is obtained per channel.
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来源期刊
CiteScore
6.90
自引率
18.80%
发文量
292
审稿时长
4.9 months
期刊介绍: AEÜ is an international scientific journal which publishes both original works and invited tutorials. The journal''s scope covers all aspects of theory and design of circuits, systems and devices for electronics, signal processing, and communication, including: signal and system theory, digital signal processing network theory and circuit design information theory, communication theory and techniques, modulation, source and channel coding switching theory and techniques, communication protocols optical communications microwave theory and techniques, radar, sonar antennas, wave propagation AEÜ publishes full papers and letters with very short turn around time but a high standard review process. Review cycles are typically finished within twelve weeks by application of modern electronic communication facilities.
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