光声系统的远心准直光学系统设计

IF 0.8 4区医学 Q4 BIOPHYSICS

Journal of Mechanics in Medicine and Biology Pub Date : 2023-10-07 DOI:10.1142/s0219519423401061

Hojong Choi, Jaemyung Ryu

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引用次数: 0

摘要

目前的光声系统在临床水平上面临图像分辨率方面的技术瓶颈。因此，在光学系统中提出了各种方法来提高处理声信号时的分辨率。为了提高成像分辨率，需要研制一种新型的远心准直光学系统。研制了变焦1、变焦2、变焦3三种变焦情况下的远心准直系统。所设计的远心准直光学系统可获得0.3°的远心角，最大衍射像差小于- 0.27%。因此，我们可以得出结论，设计的远心准直器设计可以用于提高光声系统在目标表面的图像分辨率，因为设计的准直器光学系统可以在很宽的范围内提供非常小的远心角变化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Telecentric Collimator Optical System Design for Photoacoustic System

Current photoacoustic systems face a technical bottleneck in terms of image resolution at the clinical level. Therefore, various methods in the optical system are proposed for improving resolution while processing acoustic signals. To improve the image resolution, a novel optical system design for a telecentric collimator optical system needs to be developed. The telecentric collimator system with three different cases (zoom 1, zoom 2, and zoom 3) was developed with different focal length variances. The designed telecentric collimator optical system can obtain a telecentric angle of 0.3° and maximum diffraction aberration of less than −0.27%. Therefore, we can conclude that a designed telecentric collimator design can be useful for improving the image resolution of the photoacoustic system at the target surface because the designed collimator optical system can provide a very small telecentric angle variance over a wide range.

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来源期刊

Journal of Mechanics in Medicine and Biology 工程技术-工程：生物医学

CiteScore

1.20

自引率

12.50%

发文量

144

审稿时长

2.3 months

期刊介绍： This journal has as its objective the publication and dissemination of original research (even for "revolutionary concepts that contrast with existing theories" & "hypothesis") in all fields of engineering-mechanics that includes mechanisms, processes, bio-sensors and bio-devices in medicine, biology and healthcare. The journal publishes original papers in English which contribute to an understanding of biomedical engineering and science at a nano- to macro-scale or an improvement of the methods and techniques of medical, biological and clinical treatment by the application of advanced high technology. Journal''s Research Scopes/Topics Covered (but not limited to): Artificial Organs, Biomechanics of Organs. Biofluid Mechanics, Biorheology, Blood Flow Measurement Techniques, Microcirculation, Hemodynamics. Bioheat Transfer and Mass Transport, Nano Heat Transfer. Biomaterials. Biomechanics & Modeling of Cell and Molecular. Biomedical Instrumentation and BioSensors that implicate ''human mechanics'' in details. Biomedical Signal Processing Techniques that implicate ''human mechanics'' in details. Bio-Microelectromechanical Systems, Microfluidics. Bio-Nanotechnology and Clinical Application. Bird and Insect Aerodynamics. Cardiovascular/Cardiac mechanics. Cardiovascular Systems Physiology/Engineering. Cellular and Tissue Mechanics/Engineering. Computational Biomechanics/Physiological Modelling, Systems Physiology. Clinical Biomechanics. Hearing Mechanics. Human Movement and Animal Locomotion. Implant Design and Mechanics. Mathematical modeling. Mechanobiology of Diseases. Mechanics of Medical Robotics. Muscle/Neuromuscular/Musculoskeletal Mechanics and Engineering. Neural- & Neuro-Behavioral Engineering. Orthopedic Biomechanics. Reproductive and Urogynecological Mechanics. Respiratory System Engineering...