An Adaptive Algorithm for Wavefront Reconstruction Based on a Shack-Hartmann Sensor

J4 ›› 2013, Vol. 30 ›› Issue (4): 482-489.

• Laser Applications • Previous Articles Next Articles

An Adaptive Algorithm for Wavefront Reconstruction Based on a Shack-Hartmann Sensor

LI Zhan-guo LI Bang-ming LI Chang-wei ZHANG Si-jiong

1 Nanjing Institute of Astronomical Optics and Technology，National Astronomical Observatories, Chinese Academy of Sciences, Nanjing 210042, China; 2 Key Laboratory of Astronomical Optics and Technology, Chinese Academy of Sciences, Nanjing 210042, China; 3 University of Chinese Academy of Sciences, Beijing 1000049, China ?

Received:2012-09-10 Revised:2012-11-21 Published:2013-07-28 Online:2013-07-06

Abstract

Abstract: Wavefront reconstruction is of great importance in adaptive optics. Accuracy of the reconstruction has a significant effect on performances of an adaptive optics system. An adaptive algorithm for wavefront reconstruction based on a reference-free Shack-Hartmann wavefront sensor is proposed. In this approach information needed for wavefront reconstruction, including the detection windows, the actual centroids, the reference centroids, and the reconstruction area, can be automatically determined according to the characteristics of the obtained spot image of the Shack-Hartmann. The effects of different reference centroids on the reconstruction result of the incident aberrations are discussed. The reconstruction algorithm is experimentally verified by compensating phase distortion produced by artificial atmospheric turbulence in laboratory through an adaptive optics system. The experimental results show that wavefront aberrations caused by the atmospheric turbulence can be reduced to below 0.1 λ, which makes the quality of images close to the diffraction limit. The wavefront construction algorithm is an attractive and practical alternative to an adaptive optics system for telescopes.

Key words: adaptive optics, wavefront reconstruction, adaptive algorithm, Shack-Hartmann wavefront sensor, centroid detection

CLC Number:

O439
TN247

LI Zhan-guo LI Bang-ming LI Chang-wei ZHANG Si-jiong. An Adaptive Algorithm for Wavefront Reconstruction Based on a Shack-Hartmann Sensor[J]. J4, 2013, 30(4): 482-489.

References

[1]F. Roddier.Adaptive optics in astronomy [J].,1999,:- [2]Yuan Ke'e, Zhu Wenyue, Rao Ruizhong.Simultaneous Measurements on Scintillation and Phase Fluctuation of Light Propagation through Atmospheric Turbulence by Shack-Hartmann Wavefront Sensor[J].Acta Optica Sinica (光学学报),2008,28(9):1659-1663 [3]Jiang Wenhan, Xian Hao, Yang Zeping.Application of Shack-Hartmann wavefront sensor[J].Chinese Journal of Quantum Electronics (量子电子学报),1998,15(2):228-235 [4]B. C. Platt, R. Shack.History and Principles of Shack-Hartmann Wavefront Sensing[J].Journal of Refractive Surgery,2001,17:573- [5]P. M. Prieto, FVargas-Martin.Analysis of the performance of the Hartmann-Shack sensor in the human eye[J].J. Opt. Soc. Am. A,2000,17(8):1388-1398 [6]Wang Wei, Chen Huaixin.New method for centroid detecting of focal spot based on optimizing detecting window[J].High Power Laser and Particle Beams (强激光与粒子束),2006,18(08):1249-1252 [7]Shen Feng, Jiang Wenhan.A Method for Improving the Centroid Sensing Accuracy Threshold of HartmannWavefront Sensor[J].Opto-Electronic Engineering (光电工程),1997,24(3):1-8 [8]Ren Jianfeng, Rao Changhui, Li Mingquan.An Adaptive Threshold Selection Method for Hartmann-Shack Wavefront Sensor[J].Opto-Electronic Engineering (光电工程),2002,29(1):1-5 [9]X. M. Yin, XLi, L. P. Zhao et al.. .Adaptive thresholding and dynamic windowing method for automatic centroid detection of digital Shack-Hartmann wavefront sensor[J].Applied Optics,2009,48(32):6088-6098 [10]S. Thomas, T. Fusco, A. Tokovinin, M. Nicolle et al.. .Comparison of centroid computation algorithms in a ShackHartmann sensor[J].Mon. Not. R. Astron. Soc,2006,371:323-336 [11]M. Nicolle, TFusco, G. Rousset et al.. .Improvement of Shack-Hartmann wavefront sensor measurement for extreme adaptive optics[J].Opt. Lett,2004,29(23):2743-2745 [12]J. Wang, D. Silva..Wave-front interpretation with Zernike polynomials[J].Applied Optics,1980,19(9):1510-1518 [13]Zhang Jinping, Zhang Zhongyu, Zhang Xuejun et al.Algorithm for extending dynamic range of Shack-Hartmann wavefront sensor[J].Acta Optica Sinica (光学学报),2011,31(18):0812006- [14]W. H. Southwell.Wave-front estimation from wave-front slope measurements[J].Opt. Soc. Am,1980,70:998-1006 [15]Li Bangming, Li Changwei, Zhang Sijiong.Dynamic Optimization Method for Modal Control of Adaptive Optics System[J].Acta Optica Sinica (光学学报),2012,32(4):0401005-

An Adaptive Algorithm for Wavefront Reconstruction Based on a Shack-Hartmann Sensor

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 7

Recommended Articles

Metrics

Comments

[1]	YAN Zhiwu , GU Naiting , RAO Changhui , . A calibration method for temperature sensors of large ground⁃based solar telescope [J]. Chinese Journal of Quantum Electronics, 2023, 40(4): 588-596.
[2]	HUANG Jian, ∗, DENG Ke, . Theoretical challenges in the research of atmospheric coherent laser communication [J]. Chinese Journal of Quantum Electronics, 2020, 37(5): 556-565.
[3]	BO Yong, BIAN Qi, PENG Qinjun, XU Zuyan, WEI Kai, ZHANG Yudong, FENG Lu, XUE Suijian. Development of Sodium Beacon Laser [J]. Chinese Journal of Quantum Electronics, 2020, 37(4): 430-446.
[4]	HUANG Jiaying, ZHU Lei, YANG Feng, RAO Changhui, ∗. Correction of shape and position errors of distributed holographic aperture imaging system [J]. Chinese Journal of Quantum Electronics, 2020, 37(4): 456-465.
[5]	ZHAO Wang, ZHAO Mengmeng, WANG Shuai, YANG Ping, . Influence of near ground phase vortex on the correction of adaptive optics [J]. Chinese Journal of Quantum Electronics, 2020, 37(4): 466-476.
[6]	LI Nan, QIAO Chunhong, ZHANG Pengfei, FENG Xiaoxing, FAN Chengyu. Research of Laser Propagation in the Non-Kolmogorov Turbulence Atmosphere and its Phase Compesation [J]. Chinese Journal of Quantum Electronics, 2019, 36(6): 745-751.
[7]	YANG Ke, FU Dongming, ZHANG Jinping, ZHENG Liehua. Wavefront reconstruction of aspherical surface [J]. J4, 2016, 33(1): 1-7.