Design a common optical path system for near- and far-field detection of optical phased array chips

Yanhua Shen; Xingxin Fan; Zhiyu Chen; Jiawei Huang; Rongguo Lu; Guangbiao Wang; Zizheng Cao; Yong Liu

doi:10.1117/1.OE.63.2.025106

Design a common optical path system for near- and far-field detection of optical phased array chips

Yanhua Shen, Xingxin Fan, Zhiyu Chen, Jiawei Huang, Rongguo Lu (Corresponding author), Guangbiao Wang (Corresponding author), Zizheng Cao, Yong Liu

Optical Access and Indoor Networks

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Abstract

With the development of optical phased array (OPA) chips, it is urgent to design an optical system for detecting OPA chips. We propose a near- and far-field common optical path detection system adapted to commercial cameras. By changing the focal length of the rear set of lenses, the optical system can be used to realize the near-field detection, far-field field of view (FOV) detection, and far-field resolution detection of OPA chips. The object spatial resolution of the near-field system is 1.11 μm, and the far-field system can achieve ±45 deg FOV detection and 0.0185 deg angular resolution. Simulation results show that it can be used to characterize the far-field spot with 0.1 deg resolution. The optical system is designed with spherical lenses, and its imaging performance approaches the diffraction limit.

Original language	English
Article number	025106
Number of pages	15
Journal	Optical Engineering
Volume	63
Issue number	2
DOIs	https://doi.org/10.1117/1.OE.63.2.025106
Publication status	Published - 1 Feb 2024

Bibliographical note

Publisher Copyright:
© 2024 Society of Photo-Optical Instrumentation Engineers (SPIE)

Keywords

a common optical path system
near- and far-field detection system
optical design
optical phased array chips
zoom lens

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abstract = "With the development of optical phased array (OPA) chips, it is urgent to design an optical system for detecting OPA chips. We propose a near- and far-field common optical path detection system adapted to commercial cameras. By changing the focal length of the rear set of lenses, the optical system can be used to realize the near-field detection, far-field field of view (FOV) detection, and far-field resolution detection of OPA chips. The object spatial resolution of the near-field system is 1.11 μm, and the far-field system can achieve ±45 deg FOV detection and 0.0185 deg angular resolution. Simulation results show that it can be used to characterize the far-field spot with 0.1 deg resolution. The optical system is designed with spherical lenses, and its imaging performance approaches the diffraction limit.",

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AU - Chen, Zhiyu

AU - Huang, Jiawei

AU - Lu, Rongguo

AU - Wang, Guangbiao

AU - Cao, Zizheng

AU - Liu, Yong

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N2 - With the development of optical phased array (OPA) chips, it is urgent to design an optical system for detecting OPA chips. We propose a near- and far-field common optical path detection system adapted to commercial cameras. By changing the focal length of the rear set of lenses, the optical system can be used to realize the near-field detection, far-field field of view (FOV) detection, and far-field resolution detection of OPA chips. The object spatial resolution of the near-field system is 1.11 μm, and the far-field system can achieve ±45 deg FOV detection and 0.0185 deg angular resolution. Simulation results show that it can be used to characterize the far-field spot with 0.1 deg resolution. The optical system is designed with spherical lenses, and its imaging performance approaches the diffraction limit.

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Design a common optical path system for near- and far-field detection of optical phased array chips

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