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Proposal and demonstration of germanium-on-silicon lock-in pixels for indirect time-of-flight based three-dimensional sensing

We propose the use of germanium-on-silicon technology for indirect time-of-flight based three-dimensional sensing, and demonstrate a novel lock-in pixel featuring high quantum efficiency and large frequency bandwidth. Compared to silicon pixels, germanium-on-silicon pixels simultaneously maintain a high quantum efficiency and a high demodulation contrast deep into GHz frequency regime, which enable consistently superior depth accuracy in both indoor and outdoor scenarios. Physical model, numerical simulation, device fabrication and characterization, system performance comparison, and laser safety analysis are presented. Our work paves a new path to high-performance time-of-flight rangers and imagers, as well as potential adoption of lasers operated at a longer near infrared wavelength that falls outside of the operation window of silicon pixels.

preprint2020arXivOpen access
N. NaS. -L. ChengH. -D. LiuM. -J. YangC. -Y. ChenK. -C. ChuH. -W. ChenY. -T. ChouC. -T. LinW. -H. LiuC. -F. LiangC. -L. ChenS. -W. ChuB. -J. ChenY. -F. LyuS. -L. Chen
physics.ins-det
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Open access16 authors1 topic
Imported metadata coverageMissing code, dataset, citation and institution fields are tracked without dominating the paper.Details
Citations: 0Reviews: 0Saves: 0Code: not linkedDataset: not linkedInstitutions: 0

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N. NaS. -L. ChengH. -D. LiuM. -J. YangC. -Y. ChenK. -C. ChuH. -W. ChenY. -T. ChouC. -T. LinW. -H. LiuC. -F. LiangC. -L. ChenS. -W. ChuB. -J. ChenY. -F. LyuS. -L. Chen

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