Design and Analysis of a 10× Optical Zoom System for an LWIR Camera

Ok, Chang-Min; Park, Sungchan

doi:10.3807/josk.2014.18.5.574

Cited by 5 publications

(1 citation statement)

References 12 publications

(14 reference statements)

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“…Traditional zoom imaging devices are usually large in overall size and take a long time to change the focal length by mechanical movement [ 1 , 2 , 3 , 4 , 5 , 6 ]. To achieve a lightweight, fast response and no mechanical disturbance of the zoom system, liquid lenses provide a solution; liquid lenses vary focal length by changing the radius of the liquid–liquid (L–L) surface.…”

Section: Introductionmentioning

confidence: 99%

Deep Learning Enables Optofluidic Zoom System with Large Zoom Ratio and High Imaging Resolution

Jian-cheng

Kuang

Liu

et al. 2023

Sensors

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Due to the relatively low optical power of a liquid lens, it is usually difficult to achieve a large zoom ratio and a high-resolution image simultaneously in an optofluidic zoom imaging system. We propose an electronically controlled optofluidic zoom imaging system combined with deep learning, which achieves a large continuous zoom change and a high-resolution image. The zoom system consists of an optofluidic zoom objective and an image-processing module. The proposed zoom system can achieve a large tunable focal length range from 4.0 mm to 31.3 mm. In the focal length range of 9.4 mm to 18.8 mm, the system can dynamically correct the aberrations by six electrowetting liquid lenses to ensure the image quality. In the focal length range of 4.0–9.4 mm and 18.8–31.3 mm, the optical power of a liquid lens is mainly used to enlarge the zoom ratio, and deep learning enables the proposed zoom system with improved image quality. The zoom ratio of the system reaches 7.8×, and the maximum field of view of the system can reach ~29°. The proposed zoom system has potential applications in camera, telescope and so on.

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Section: Introductionmentioning

confidence: 99%

Deep Learning Enables Optofluidic Zoom System with Large Zoom Ratio and High Imaging Resolution

Jian-cheng

Kuang

Liu

et al. 2023

Sensors

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Design of IR zoom lens system for long-range detection in uncooled LWIR camera

Mowafy¹,

EL-Dessouky

Medhat

2022

J Opt

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A new compact optical zoom lens system with variable focal length 100–200 mm for uncooled LWIR (8–12 μm) camera is designed. It is used for long-range detection. The optimized IR zoom lens consists of four group elements. TheF/# of the zoom system isF/1.4 at all zoom positions. Its performance reaches the diffraction limit at each focal length position. Moreover, optical design and image quality are calculated by ZEMAX optical software. The imaging quality performance is steady during zoom process. In addition to the above benefits, the optimized IR zoom lens is light and compact (200 mm) with 4 lenses and only one of them has diffractive surface to lower production cost. Upon applying anti-reflection coating, the total transmittance of the optical system is enhanced from 2 to 99% atλ = 10 µm.

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Structural optical design of multi-group, high zoom ratio optical systems

Li,

Chen,

et al. 2024

Optics Communications

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Design and Analysis of a 10× Optical Zoom System for an LWIR Camera

Cited by 5 publications

References 12 publications

Deep Learning Enables Optofluidic Zoom System with Large Zoom Ratio and High Imaging Resolution

Deep Learning Enables Optofluidic Zoom System with Large Zoom Ratio and High Imaging Resolution

Design of IR zoom lens system for long-range detection in uncooled LWIR camera

Structural optical design of multi-group, high zoom ratio optical systems

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