基于光学相位共轭的数字化波前整形技术（特邀）

Yuecheng Shen; Hanpeng Liang; Jiayu Zhao; Jiawei Luo

doi:10.3788/IRLA20220256

基于光学相位共轭的数字化波前整形技术（特邀）

Translated title of the contribution: Wavefront shaping technology based on digital optical phase conjugation (invited)

Yuecheng Shen
, Hanpeng Liang
, Jiayu Zhao
, Jiawei Luo

Sun Yat-Sen University

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Optical scattering inherent in biological tissue prohibits optical technologies from being widely used in biomedical applications. Wavefront shaping treats optical scattering as a deterministic process, enabling the control of scattered light by point-by-point phase compensation through spatial light modulators. Among various wavefront shaping technologies, digital optical phase conjugation controls the largest number of degrees of freedom and has the fastest speed, which is suitable for biomedical applications such as live-tissue imaging, manipulation, and therapy. This paper will describe the development of digital optical phase conjugation, discuss the main technological challenges encountered, and speculate on future applications.

Translated title of the contribution	Wavefront shaping technology based on digital optical phase conjugation (invited)
Original language	Chinese (Traditional)
Article number	20220256
Journal	Infrared and Laser Engineering
Volume	51
Issue number	8
DOIs	https://doi.org/10.3788/IRLA20220256
State	Published - Aug 2022
Externally published	Yes

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title = "基于光学相位共轭的数字化波前整形技术（特邀）",

abstract = "Optical scattering inherent in biological tissue prohibits optical technologies from being widely used in biomedical applications. Wavefront shaping treats optical scattering as a deterministic process, enabling the control of scattered light by point-by-point phase compensation through spatial light modulators. Among various wavefront shaping technologies, digital optical phase conjugation controls the largest number of degrees of freedom and has the fastest speed, which is suitable for biomedical applications such as live-tissue imaging, manipulation, and therapy. This paper will describe the development of digital optical phase conjugation, discuss the main technological challenges encountered, and speculate on future applications.",

keywords = "biomedical imaging, optical phase conjugation, ultrasonic modulation, wavefront shaping",

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doi = "10.3788/IRLA20220256",

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AU - Shen, Yuecheng

AU - Liang, Hanpeng

AU - Zhao, Jiayu

AU - Luo, Jiawei

PY - 2022/8

Y1 - 2022/8

N2 - Optical scattering inherent in biological tissue prohibits optical technologies from being widely used in biomedical applications. Wavefront shaping treats optical scattering as a deterministic process, enabling the control of scattered light by point-by-point phase compensation through spatial light modulators. Among various wavefront shaping technologies, digital optical phase conjugation controls the largest number of degrees of freedom and has the fastest speed, which is suitable for biomedical applications such as live-tissue imaging, manipulation, and therapy. This paper will describe the development of digital optical phase conjugation, discuss the main technological challenges encountered, and speculate on future applications.

AB - Optical scattering inherent in biological tissue prohibits optical technologies from being widely used in biomedical applications. Wavefront shaping treats optical scattering as a deterministic process, enabling the control of scattered light by point-by-point phase compensation through spatial light modulators. Among various wavefront shaping technologies, digital optical phase conjugation controls the largest number of degrees of freedom and has the fastest speed, which is suitable for biomedical applications such as live-tissue imaging, manipulation, and therapy. This paper will describe the development of digital optical phase conjugation, discuss the main technological challenges encountered, and speculate on future applications.

KW - biomedical imaging

KW - optical phase conjugation

KW - ultrasonic modulation

KW - wavefront shaping

UR - https://www.scopus.com/pages/publications/85138490687

U2 - 10.3788/IRLA20220256

DO - 10.3788/IRLA20220256

M3 - 文章

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SN - 1007-2276

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JO - Infrared and Laser Engineering

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IS - 8

M1 - 20220256

ER -

基于光学相位共轭的数字化波前整形技术（特邀）

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