Modeling and Simulation of LiDAR Based on Single-Photon Avalanche Diode

Fig. 6. Simulation histograms of passive reset mode and active reset mode quenching circuits under the condition of the time of flight of 20 ns and the ambient light of 50×10³ lx. (a) Passive reset circuit histogram with target reflectivity of 10%; (b) active reset circuit histogram with target reflectivity of 10%; (c) passive reset circuit histogram with target reflectivity of 50%; (d) active reset circuit histogram with target reflectivity of 50%

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Fig. 7. Success rates of different TOFs for two types of circuits under ambient light of 50×10³ lx. (a) Target reflectivity is 10%; (b) target reflectivity is 50%

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Fig. 8. Histograms of single-event first-photon TDC and multi-event TDC under different conditions. (a) Histogram of single-event first-photon TDC under the ambient light of 50×10³ lx; (b) histogram of multi-event TDC under the ambient light of 50×10³ lx; (c) histogram of single-event first-photon TDC under the ambient light of 100×10³ lx; (d) histogram of multi-event TDC under the ambient light of 100×10³ lx

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Fig. 9. Success rates of single-event first-photon TDC and multi-event TDC under the target reflectivity of 10%. (a) Ambient light of 50×10³ lx; (b) ambient light of 100×10³ lx

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Fig. 10. Histograms of four combined circuit architectures. (a) Passive reset circuit+single-event first-photon TDC; (b) active reset circuit+single-event first-photon TDC; (c) passive reset circuit+multi-event TDC; (d) active reset circuit+multi-event TDC

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Fig. 11. Success rates of four combination circuits under the ambient light of 50×10³ lx and the target reflectivity of 50%

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Table 1. Key parameters of each module of the LiDAR system

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Table 1. Key parameters of each module of the LiDAR system

Part	Parameter	Symbol	Value	Unit
VCSEL	Central wavelength	$λ$	940	nm
	Peak power	$P_{T X}$	30	mW
	Pulse width	$W$	1	ns
	Oxide aperture	$V_{O A}$	50	μm
	Repetition rate	—	2	MHz
SPAD	Pixel size	$a$	50	μm
	PDE	$η_{P D E}$	15	%
	DCR	$N_{D C R}$	5	Hz/μm²
TX optical element	Focal length	$f_{T X}$	2	mm
TX optical element	Transmittance	$T_{T X}$	96	%
RX optical element	Focal length	$f_{R X}$	2	mm
	Diameter	$D_{R X}$	1	mm
	Transmittance	$T_{R X}$	96	%
	Filter bandwidth	$Δ λ$	40	nm
Quenching circuit	Dead time	$T_{d e a d}$	10	ns
TDC	LSB/bin size	—	400	ps
Others	TOF	—	20	ns
	Sunlight	$M_{B G}$	50，100	10³ lx
	Target reflectivity	$ρ_{t a r g e t}$	10，50	%
	Number of measurement period	$N_{T C S P C}$	10⁵	—

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Ran He, Liang Zhu, Junfa Dong, Zhenzhong Xiao, Yuming Dong. Modeling and Simulation of LiDAR Based on Single-Photon Avalanche Diode[J]. Laser & Optoelectronics Progress, 2024, 61(10): 1028003

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Paper Information

Category: Remote Sensing and Sensors

Received: Sep. 14, 2023

Accepted: Oct. 20, 2023

Published Online: Apr. 2, 2024

The Author Email: He Ran (heran_2013@126.com)

DOI:10.3788/LOP232126

Topics

laser devices and laser physics

Lasers and Laser Optics

Laser physics

laser manufacturing

Instrumentation, Measurement and Metrology