Design and Optimization of Low Power and Low Light Sensor: (Invited)

2020 IEEE Custom Integrated Circuits Conference (CICC) Pub Date : 2020-03-01 DOI:10.1109/CICC48029.2020.9075874

Assim Boukhayma, Antonino Caizzone, Raffaele Capoccia, C. Enz

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引用次数: 1

Abstract

The current trend towards embedding more and more light sensors in portable and wearable devices is calling for higher integration and reuse of the sensor interface electronics. In many applications, the light needs to be generated locally, which becomes the dominant source of power consumption. Power can hence be saved by making the sensor more sensitive to lower light. At low light the noise is totally dominated by the noise coming from the electronic readout chain. This paper shows how this noise can be minimized all along the readout chain, from the pixel to the ADC. It also shows that many low-light applications actually share the same readout architecture. The latter is made of the pixel including a source follower, a shared amplifier and a correlated double sampling (CDS) or correlated multiple sampling (CMS) stage that is key for eliminating the low-frequency noise and reducing the white noise for CMS. It is shown how each of these building blocks can be optimized for reaching a minimum input-referred noise. The design methodology is then illustrated by three applications, including a 0.5 etectonrms., CMOS VGA imager, a 2.6 µW PPG sensor and a 10 µW 1D time-of-flight distance ranging device.

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低功耗低光传感器的设计与优化:(特邀)

在便携式和可穿戴设备中嵌入越来越多的光传感器的趋势要求传感器接口电子器件的更高集成度和重用性。在许多应用中，光需要在本地产生，这成为功耗的主要来源。因此，通过使传感器对弱光更敏感，可以节省电力。在弱光下，噪声完全被来自电子读出链的噪声所控制。本文展示了如何在从像素到ADC的整个读出链中最小化这种噪声。它还表明，许多低光应用实际上共享相同的读出架构。后者由像素组成，包括源跟随器、共享放大器和相关双采样(CDS)或相关多重采样(CMS)级，这是消除低频噪声和降低CMS白噪声的关键。它展示了如何优化这些构建块，以达到最小的输入参考噪声。然后通过三个应用说明了设计方法，包括0.5 etectonrms。， CMOS VGA成像仪，2.6µW PPG传感器和10µW 1D飞行时间距离测距装置。

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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2020 IEEE Custom Integrated Circuits Conference (CICC)

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