激光雷达
光子计数
测距
探测器
激光器
波形
雪崩二极管
雪崩光电二极管
遥感
航程(航空)
环境科学
光学
材料科学
信号(编程语言)
失真(音乐)
漫射天空辐射
单光子雪崩二极管
光电倍增管
帧速率
激光二极管
大气模式
饱和(图论)
二极管
反射率
大气光学
动态范围
灵敏度(控制系统)
作者
Linjie Lyu,Duan Li,Tengfei Wu,Qinggai Mi,Yang Yang,Wenbin Zhou,Lijun Xu
标识
DOI:10.1109/tim.2025.3619271
摘要
Light Detection and Ranging (LiDAR) with InGaAs/InP Single Photon Avalanche Diodes (SPADs) offers high sensitivity and exceptional temporal resolution, enabling a wide range of applications in target detection, earth mapping, gas detection, and atmospheric exploration. However, it struggles with a long accumulation time to determine the reflectivity and depth of the target. In this paper, a high counting-rate single-photon LiDAR system was developed to decrease accumulation time and improve detection and imaging speed. A Markov-chain steady-state model was introduced for the first time to relate counting rate, signal flux, and laser repetition frequency. This model corrects waveform distortion at high counting rates and substantially enhances the accuracy of both depth and reflectivity measurements. The adjustable laser repetition rates resolve distance ambiguities arising from high counting rate, enhancing detection and imaging range. Simulations and experiments were carried out to verify the performances of the LiDAR and the established model. The LiDAR systems achieved an average photon counting rate of 717 kHz, which was nearing the saturation counting rate of the InGaAs/InP single-photon detector (833 kHz). The LiDAR systems in building mapping was verified by the 3D imaging and the time consumption of 0.2 ms per pixel, which achieved 3D imaging of buildings from 40 to 120 m with sub centimeter depth accuracy when the laser repetition rate was 3.125 MHz (unambiguous range 48 m).
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