Shunt-Shunt Feedback Inverter Transimpedance Amplifier Design for Capsule Endoscopy

2023 19th International Conference on Synthesis, Modeling, Analysis and Simulation Methods and Applications to Circuit Design (SMACD) Pub Date : 2023-07-03 DOI:10.1109/SMACD58065.2023.10192154

Emrah Peker, O. Ferhanoğlu, M. B. Yelten

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Abstract

This work reports on the design and performance of a shunt-shunt feedback inverter transimpedance amplifier (TIA). The proposed design is to be employed in capsule endoscopy with optical imaging or similar biomedical systems. The design is implemented in 180 nm CMOS technology with the performance targets of low area, low power, low complexity, high gain, and low noise. Alternative feedback resistor design approaches are proposed to achieve lower dispersion in transimpedance gain (TI gain), where one of the approaches proves superior in terms of area and performance. The design achieves 96 dBΩ gain with sub-0.6 dBΩ standard deviation in post-layout Monte Carlo simulations. The total input capacitance is 10 pF (from the photodiode), and the achieved −3 dB cut-off frequency is 50 MHz. The achieved total integrated input noise is 0.63 μA, and the total power consumption is 0.26 mW. Compared to similar works, the design improves power consumption and complexity without losing noise, and the TI gain performance considerably by keeping a narrow bandwidth, which is sufficient for the target operation.

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胶囊内窥镜并联反馈逆变器跨阻放大器设计

本文报道了一种并联反馈逆变器跨阻放大器(TIA)的设计和性能。所提出的设计将用于胶囊内窥镜与光学成像或类似的生物医学系统。该设计采用180nm CMOS技术实现，具有低面积、低功耗、低复杂度、高增益和低噪声的性能目标。为了在跨阻增益(TI增益)中实现更低的色散，提出了几种反馈电阻设计方法，其中一种方法在面积和性能方面证明了优越性。该设计在布局后蒙特卡罗模拟中获得96 dBΩ增益，标准差低于0.6 dBΩ。总输入电容为10pf(来自光电二极管)，实现−3db截止频率为50mhz。实现的总集成输入噪声为0.63 μA，总功耗为0.26 mW。与同类产品相比，该设计在不损失噪声的情况下提高了功耗和复杂性，并且通过保持足够的目标操作的窄带宽而大大提高了TI增益性能。

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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2023 19th International Conference on Synthesis, Modeling, Analysis and Simulation Methods and Applications to Circuit Design (SMACD)

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