A 640×480 Indirect Time-of-Flight CMOS Image Sensor with 4-tap 7-μm Global-Shutter Pixel and Fixed-Pattern Phase Noise Self-Compensation Scheme

2019 Symposium on VLSI Circuits Pub Date : 2019-06-09 DOI:10.23919/VLSIC.2019.8778090
Min-Sun Keel, Young-Gu Jin, Youngchan Kim, Daeyun Kim, Yeomyung Kim, M. Bae, Bumsik Chung, S. Son, Hogyun Kim, Taemin An, Sungsoo Choi, T. Jung, Yonghun Kwon, Sung-Uk Seo, Sae-Young Kim, Kwanghyuk Bae, Seung-Chul Shin, Myoungoh Ki, Changrok Moon, H. Ryu
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引用次数: 16

Abstract

${A}640 \times 480$ indirect Time-of-Flight (ToF) CMOS image sensor has been designed with 4-tap $7-\mu \mathrm{m}$ global-shutter pixel in 65-nm back-side illumination (BSI) process. With novel 4tap pixel structure, we achieved motion artifact-free depth map. Column fixed-pattern phase noise (FPPN) is reduced by introducing alternative control of the clock delay propagation path in the photo-gate driver. As a result, motion artifact and column FPPN are not noticeable in the depth map. The proposed ToF sensor shows depth noise less than 0.62% with 940-nm illuminator over the working distance up to 400 cm, and consumes 197 mW for VGA, which is 0.64 pW/pixel.
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一种具有4分频7 μm全局快门像素和固定模式相位噪声自补偿方案的640×480间接飞行时间CMOS图像传感器
采用65纳米背面照明(BSI)工艺,设计了${A}640 \times 480$间接飞行时间(ToF) CMOS图像传感器,具有$7-\mu \ maththrm {m}$全局快门像素。采用新颖的4tap像素结构,实现了无运动伪影的深度图。通过在光门驱动器中引入时钟延迟传播路径的替代控制,降低了柱固定模式相位噪声(FPPN)。因此,运动伪影和列FPPN在深度图中不明显。所提出的ToF传感器在工作距离达400 cm的940 nm光源下显示深度噪声小于0.62%,VGA功耗为197 mW,即0.64 pW/像素。
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2019 Symposium on VLSI Circuits
2019 Symposium on VLSI Circuits
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