The detection principle and performance of the pseudo-random single photon counting ranging (PSPCR) Lidar system are investigated. The detection probability and single photon detection efficiency (SPDE) of the macro code for the PSPCR Lidar system are derived based on statistical theory. The effects of the echo primary electrons number and the dead time on the detection probability and SPDE are analyzed. The detection probability increases with the increase of the primary electron number and tends toward saturation. The change of dead time length has little effect on the detection probability of the macro code, especially when the number of echo primary electrons is large. However, the length of dead time is inversely proportional to the number of detected codes. The longer the dead time, the fewer the number of detected codes, and the worse the ranging performance. The signal-to-noise ratio (SNR) of the PSPCR Lidar is analyzed based on the cross-correlation function. The Monte Carlo simulation results show that the PSPCR Lidar has a satisfactory SNR even in a high noise level. As the number of signal primary electrons increases, the SNR gradually increases and tends to be saturated. As the noise increases, the SNR gradually decreases, and the greater the noise, the more severe the SNR decreases. At the same time, based on the assumption that the power of the single code in Gaussian distribution and the time resolution of the photon counting module are less than the code width, the theoretical formula of the range error is deduced. The effects of the echo signal primary electron number and code width on the range error are analyzed. The results show that the fewer the primary electron numbers or the narrower the code width, the smaller the range error of the PSPCR Lidar system. The range error of the PSPCR Lidar system is verified by Monte Carlo simulation. The simulation results are in good agreement with the theoretical analysis. (C) 2018 Optical Society of America.
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机译:研究了伪随机单光子计数测距(PSPCR)LIDAR系统的检测原理和性能。基于统计理论导出PSPCR激光雷达系统的宏码的检测概率和单光子检测效率(SPDE)。分析了回声初级电子数和死区时间对检测概率和SPDE的影响。检测概率随着主电子数的增加而增加并且趋于饱和。死区时间长度的变化对宏码的检测概率几乎没有影响,尤其是当回声初级电子的数量大时。然而,死区时间的长度与检测到的代码的数量成反比。死区时间越长,检测到的代码的数量越越大,测距性能越差。基于互相关函数分析PSPCR LIDAR的信噪比(SNR)。 Monte Carlo仿真结果表明,即使在高噪声水平中,PSPCR LIDAR也具有令人满意的SNR。随着信号初级电子的数量增加,SNR逐渐增加并且趋于饱和。随着噪声的增加,SNR逐渐降低,噪音越大,SNR的严重程度越严重。同时,基于假设高斯分布中的单个代码的功率以及光子计数模块的时间分辨率小于代码宽度,推导出范围误差的理论公式。分析了回声信号主电子数和代码宽度对范围误差的影响。结果表明,初级电子数字或较窄的代码宽度较窄,PSPCR激光雷达系统的范围误差越小。 PSPCR LIDAR系统的速度误差由Monte Carlo仿真验证。仿真结果与理论分析吻合良好。 (c)2018年光学学会。
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