Methods for improving imaging quality of a small-distance high-speed rotational reflection tracking system

Haoran Liu; Bin Wu; Luyuan Feng; Jianwei Zhang; Fei Fan; Zhen Zhang; Zefeng Sun; Zongyang Zhao; Jiehu Kang

doi:10.1364/AO.520307

Applied Optics
Vol. 63,
Issue 11,
pp. 2981-2993
(2024)
•https://doi.org/10.1364/AO.520307

Methods for improving imaging quality of a small-distance high-speed rotational reflection tracking system

Haoran Liu, Bin Wu, Luyuan Feng, Jianwei Zhang, Fei Fan, Zhen Zhang, Zefeng Sun, Zongyang Zhao, and Jiehu Kang

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Haoran Liu, Bin Wu, Luyuan Feng, Jianwei Zhang, Fei Fan, Zhen Zhang, Zefeng Sun, Zongyang Zhao, and Jiehu Kang, "Methods for improving imaging quality of a small-distance high-speed rotational reflection tracking system," Appl. Opt. 63, 2981-2993 (2024)

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Abstract

The imaging quality of a rotational reflection high-speed tracking system is greatly affected by the optical characteristics of the reflector and the depth of field limitations of the imaging system, especially for tracking systems working in small distances. In order to improve the imaging quality, this paper focused on two factors that affect the imaging quality: double vision caused by the optical characteristics of reflectors and blurring caused by the depth of field of imaging systems. This paper quantified the impact of these two factors on imaging through theoretical analysis, proposed a method of changing the hardware position, and conducted a simulation and experiments. The results show that the proposed solution in this paper can effectively improve the imaging quality of the system. The content studied in this paper has certain significance in the field of high-speed tracking of rotating reflectors and can provide reference for relevant researchers.

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	Light Intensity Expression
$A$	$E R (θ_{1}, θ_{2})$
$B$	$E [1 - R (θ_{1}, θ_{2})] [1 - R (θ_{2}, θ_{1})]$
$C$	$E [1 - R (θ_{1}, θ_{2})] R (θ_{2}, θ_{1}) [1 - R (θ_{2}, θ_{1})]$
$D$	$E [1 - R (θ_{1}, θ_{2})] R^{2} (θ_{2}, θ_{1}) [1 - R (θ_{2}, θ_{1})]$

Personal Computer	Dell Inspiron 16 7610
CPU	11th Gen Intel Core i7-11800H
RAM	32.0 GB
Computer System	Windows 11
Software	Matlab R2018b

Incident Angle	A	B	C	D
20	0.04027	0.9211	0.03709	0.001493
30	0.04152	0.9187	0.03815	0.001584
40	0.04573	0.9106	0.04165	0.001905
50	0.05766	0.8881	0.05120	0.002953
60	0.08919	0.8296	0.07399	0.006599
70	0.17155	0.6872	0.11752	0.020123

COMS	Nikon 1-inch CMOS
Size of COMS (mm)	$13.2 \times 8.8$
Number of pixels	$720 \times 480$
Size of pixels (µm)	18.3
Aperture	F5.6
Field of view coefficient	0.07
Limit value of diffuse spots	3
Diameter size of diffuse spots (µm)	54.9

Imaging System	Since Vision SH6-113
Reflector drive system	Panasonic MSMF092L1U2M
Trigger system	GTRIC EX-DN10
MCU	STM32F407
PC	Dell Inspiron 16 7610
High-speed target	Soft bullet gun

Abstract

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Tables (5)

Equations (16)

Applied Optics