32 × 64 SPAD Imager Using 2-bit In-Pixel Stack-Based Memory for Low-Light Imaging

Hsi Hao Huang; Tzu Yun Huang; Chun Hsien Liu; Sheng Di Lin; Chen Yi Lee

doi:10.1109/JSEN.2023.3299276

32 × 64 SPAD Imager Using 2-bit In-Pixel Stack-Based Memory for Low-Light Imaging

Hsi Hao Huang^*, Tzu Yun Huang, Chun Hsien Liu, Sheng Di Lin, Chen Yi Lee

^*此作品的通信作者

研究成果: Article › 同行評審

7 引文斯高帕斯（Scopus）

摘要

This article presents a high-detection rate single-photon avalanche diode (SPAD) imaging chip designed for photon-sensing applications. The test chip includes two essential design techniques: passive quenching active clock-drive reset (PQACR) to maximize the detection window and in- pixel stack-based memory (IPSM) to reduce the effective dead time. PQACR architecture achieves 97.5% coverage detection window with minimal photon loss using a single transistor, while the IPSM architecture reduces the effective dead time from 33 to 22 ns with 28 transistors, overcoming the dead-time limitation issue in photon-counting designs. A test chip with a 32 × 64 array has been fabricated in Taiwan semiconductor manufacturing company (TSMC) 0.18- μm HV CMOS process. Experimental results demonstrate that the proposed chip achieves less dead time and photon loss, making it well suited for high-speed and low-light imaging applications.

原文	English
頁（從 - 到）	19272-19281
頁數	10
期刊	IEEE Sensors Journal
卷	23
發行號	17
DOIs	https://doi.org/10.1109/JSEN.2023.3299276
出版狀態	Published - 1 9月 2023

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10.1109/JSEN.2023.3299276

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title = "32 × 64 SPAD Imager Using 2-bit In-Pixel Stack-Based Memory for Low-Light Imaging",

abstract = "This article presents a high-detection rate single-photon avalanche diode (SPAD) imaging chip designed for photon-sensing applications. The test chip includes two essential design techniques: passive quenching active clock-drive reset (PQACR) to maximize the detection window and in- pixel stack-based memory (IPSM) to reduce the effective dead time. PQACR architecture achieves 97.5% coverage detection window with minimal photon loss using a single transistor, while the IPSM architecture reduces the effective dead time from 33 to 22 ns with 28 transistors, overcoming the dead-time limitation issue in photon-counting designs. A test chip with a 32 × 64 array has been fabricated in Taiwan semiconductor manufacturing company (TSMC) 0.18- μm HV CMOS process. Experimental results demonstrate that the proposed chip achieves less dead time and photon loss, making it well suited for high-speed and low-light imaging applications.",

keywords = "In-pixel stack-based memory (IPSM), low-light imaging, passive quenching active clock-drive reset (PQACR), photon counting, single-photon avalanche diode (SPAD)",

author = "Huang, {Hsi Hao} and Huang, {Tzu Yun} and Liu, {Chun Hsien} and Lin, {Sheng Di} and Lee, {Chen Yi}",

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AU - Huang, Tzu Yun

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AU - Lin, Sheng Di

AU - Lee, Chen Yi

PY - 2023/9/1

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KW - In-pixel stack-based memory (IPSM)

KW - low-light imaging

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32 × 64 SPAD Imager Using 2-bit In-Pixel Stack-Based Memory for Low-Light Imaging

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