Optical-digital joint design method for Cassegrain optical system with large FOV

doi:https://doi.org/10.1007/s11801-022-2068-8

Home > Archive>Volume 18, Issue 9, 2022 >525-529. DOI:https://doi.org/10.1007/s11801-022-2068-8

Optical-digital joint design method for Cassegrain optical system with large FOV
DOI:
                        https://doi.org/10.1007/s11801-022-2068-8
                    
CSTR:
                        [cstr]
                    
Author:
                        SUN LinSUN Lin
School of Opto-Electronic Engineering, Changchun University of Science and Technology, Changchun 130022, China
Find this author on All Journals
Find this author on BaiDu
Search for this author on this site
CUI QingfengCUI Qingfeng
School of Opto-Electronic Engineering, Changchun University of Science and Technology, Changchun 130022, China
Find this author on All Journals
Find this author on BaiDu
Search for this author on this site

                    
Affiliation:School of Opto-Electronic Engineering, Changchun University of Science and Technology, Changchun 130022, China
Clc Number:
Fund Project:

Article

Figures

Metrics

Reference [17]

Related [20]

Cited by

Materials

Comments

Abstract:

The field of view (FOV) of the traditional Cassegrain optical system is small, generally only 0.1°—0.2°. In order to enlarge the FOV, it is usually necessary to add correction groups or change the mirror type, but it introduces color difference and complicates the structure. In this study, an optical digital joint design method is put forward to expand the FOV of the Cassegrain optical system. First, the structural parameters of the system are optimized to control the aberration. Then, based on the wavefront aberration theory, the wavefront aberration model is constructed using Zernike polynomials, and the point spread function model is established using Fourier transform. Finally, the image is processed using the spatial transform deconvolution algorithm. The FOV of the Cassegrain optical system is expanded using only primary and secondary mirror structures. The simulation experiment of the Cassegrain optical system shows that the FOV is expanded approximately 6 times, and the imaging quality is improved. The simulation results indicate that our method is feasible.

Reference

[1] ZHOU M F, YANG H J, JIANG P, et al. Structure design of a conic lens pair for improving the transmission efficiency of a Cassegrain antenna[J]. Applied optics, 2019, 58(13)：3410-3417.

[2] MA D L. Recommended conceptual optical system design for China’s large optical-infrared telescope (LOT)[J]. Optics express, 2018, 26(1)：108-119.

[3] BRYCHIKHIN M N, CHKHALO N I, EIKHORN Y O, et al. Reflective Schmidt-Cassegrain system for large-aperture telescopes[J]. Applied optics, 2016, 55(16)：4430-4435.

[4] FISCHER R E, TADIC G B. Optical system design[M]. 2nd ed. New York：MCGRAW HILL, 2008：138-142.

[5] ROCHA M C, GONCHAROV A V. Aplanatic meniscus lens corrector for Ritchey-Chrétien telescopes[J]. Optics express, 2022, 30(4)：6076-6089.

[6] ZHANG J G, NIE Y F, FU Q, et al. Optical-digital joint design of refractive telescope using chromatic priors[J]. Chinese optics letters, 2019, 17(5)：052201.

[7] SMITH W J. Modern optical engineering[M]. 4th ed. New York：MCGRAW HILL, 2008：472-512.

[8] KUNDUR D, HATZINAKOS D. Blind image deconvolution[J]. IEEE signal processing magazine, 1996, 13(3)：43-64.

[9] JUN K, TATIANA A, FIGEN S, et al. Computational optical sensing and imaging 2021：introduction to the feature issue[J]. Applied optics, 2022, 61(9)：COSI1-

COSI4.

[10] HU Y, CUI Q F, ZHAO L D, et al. PSF model for diffractive optical elements with improved imaging performance in dual-waveband infrared systems[J]. Optics express, 2018, 26(21)：26845-26857.

[11] SUN L, CUI Q F, ZONG Z, et al. A method to increase the field of view of an imaging optical system[J]. IEEE photonics journal, 2022, 14(1)：1-10.

[12] SUN L, CUI Q F. Optical-digital integrated design method for near-eye display imaging system[J]. IEEE access, 2022, 10：50314-50322.

[13] SROUBEK F, KAMENICKY J, LU Y M. Decomposition of space-variant blur in image deconvolution[J]. IEEE signal processing letters, 2016, 23(3)：346-350.

[14] KOPRIVA I. Single-frame multichannel blind deconvolution by nonnegative matrix factorization with sparseness constraints[J]. Optics letters, 2005, 30(23)：3135-3137.

[15] MASAOKA K, YAMASHITA T, NISHIDA Y, et al. Modified slanted-edge method and multidirectional modulation transfer function estimation[J]. Optics express, 2014, 22(5)：6040-6046.

[16] XIE X F, FAN H D, WANG A D, et al. Error of the slanted edge method for measuring the modulation transfer function of imaging systems[J]. Applied optics, 2018, 57(7)：B83-B91.

Get Citation

SUN Lin, CUI Qingfeng. Optical-digital joint design method for Cassegrain optical system with large FOV[J]. Optoelectronics Letters,2022,18(9):525-529

Copy

Article Metrics

Abstract:452
PDF: 368
HTML: 0
Cited by: 0

History

Received:April 22,2022
Revised:June 23,2022
Adopted:
Online: September 15,2022
Published:

Home

About us

Authors

Editors

News

Contents

Contact us

Get Citation

Share

Article Metrics

History

Article QR Code