计算机科学
图像传感器
像素
形势意识
帧速率
光子计数
人工智能
激光雷达
单光子雪崩二极管
数码产品
架空(工程)
计算机视觉
光学
探测器
雪崩光电二极管
物理
电气工程
工程类
电信
航空航天工程
操作系统
作者
István Gyöngy,Germán Mora Martín,Alex Turpin,Alice Ruget,Abderrahim Halimi,Robert Henderson,Jonathan Leach
摘要
3D sensing devices are becoming increasingly prevalent in robotics, self-driving cars, human-computer interfaces, as well as consumer electronics. Recent years have seen single-photon avalanche diodes (SPADs) emerging as one of the key technologies underlying 3D time-of-flight sensors, with the capability to capture accurate 3D depth maps in a range of environmental conditions, and with low computational overhead. In particular, direct ToF SPADs (dToF), which measure the return time of back-scattered laser pulses, form the backbone of many automotive LIDAR systems. We here consider an advanced direct ToF SPAD imager with a 3D-stacked structure, integrating significant photon processing. The device generates photon timing histograms in-pixel, resulting in a maximum throughput of 100's of giga photons per second. This advance enables 3D frames to be captured at rates in excess of 1000 frames per second, even under high ambient light levels. By exploiting the re-configurable nature of the sensor, higher resolution intensity (photon counting) data may be obtained in alternate frames, and depth upscaled accordingly. We present a compact SPAD camera based on the sensor, enabling high-speed object detection and classification in both indoor and outdoor environments. The results suggest a significant potential in applications requiring fast situational awareness.
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