帮助 关于我们

返回检索结果

基于二维朗奇相位光栅的四波横向剪切干涉定量相位成像
Quadriwave Lateral Shearing Interferometry Quantitative Phase Imaging Based on 2D Ronchi Phase Grating

查看参考文献16篇

宋金伟 1,2   闵俊伟 1 *   袁勋 1,2   薛雨阁 1,2   姚保利 1,2 *  
文摘 定量相位成像具有无标记、非入侵及三维观测的特点,在生物医学、工业检测等领域有着显著的优势。本文提出利用二维朗奇相位光栅实现基于四波横向剪切干涉的定量相位成像的方法。理论分析了光栅周期和照明波长对四波剪切干涉的影响,得到了光栅周期与探测器像素尺寸的最佳匹配关系,论证了宽光谱光源照明下定量相位成像的可行性。实验搭建了结构紧凑的四波剪切干涉定量相位显微成像装置,实现了对PMMA微球、微透镜阵列和葡根霉菌切片的定量相位成像和测量。该装置可方便地与普通光学显微镜相结合,具有巨大的应用潜力。
其他语种文摘 Quantitative Phase Imaging(QPI)is a technique that can measure the phase map of the light field. It has the characteristics of label-free,non-invasive and three-dimensional observation and has been widely used in bioimaging and industrial inspection. A number of techniques have been developed to measure phase information of objects,including the interferometric method such as Digital Holographic Microscopy(DHM),and the non-interferometric method such as the Fourier Ptychography Microscopy (FPM),Transport of Intensity Equation(TIE)method and so on. The interferometric method has high measurement accuracy but a complex experimental setup sensitive to the environmental disturbance. The non-interferometric method recovers phase from the intensity patterns of objects,but requires iterative calculation or multiple images recorded at different positions,which makes the imaging speed slow and unsuitable for real-time observation. The quantitative phase imaging based on Quadriwave Lateral Shearing Interferometry(QLSI)has the advantages of the referenceless beam,simple configuration,high stability and fast imaging speed. In the existing studies,Cross Grating(CG),Modified Hartmann Mask (MHM),Randomly Encoded Hybrid Grating(REHG)and other splitter elements were used for QLSI. The cross grating has low diffraction efficiency and energy utilization rate(~10%)for the four beams of first-order diffraction. The MHM and REHG can concentrate the diffracted light energy on the four firstorder diffraction beams. But the MHM still has a low energy utilization rate(~37%),and the REHG has a complex structure for fabrication. This paper proposes a quantitative phase imaging method based on QLSI using a two-dimensional (2D) Ronchi phase grating. The light incident to the 2D Ronchi phase grating is diffracted mainly with energy concentrated on the four first-order diffraction beams,occupying 65.7% of the total incident energy. The object light carrying the sample′s phase information is imprinted to the 2D Ronchi phase grating and then copied into four beams,which interfere with each other to produce the quadriwave lateral shearing interferogram. The quantitative phase image of the sample is reconstructed by Fourier analysis of the interferogram. The influence of the grating period on the QLSI imaging is analyzed theoretically,and the optimal grating period is determined to be six times of the pixel size of the detector. This match can make the best use of the spatial bandwidth product of detector and achieve high resolution image. The influence of the illumination wavelength on the phase reconstruction is theoretically analyzed,which shows that the proposed method is insensitive to the illumination wavelength. The feasibility of quantitative phase imaging under wide spectral light illumination source is demonstrated. The compact QLSI module is constructed with the pixel size of 9 μm×9 μm of the detector and the period of 54 μm of the 2D Ronchi grating. The grating period is precisely six times of the pixel size,meeting the requirement of the optimal condition. The QLSI module is directly connected to a conventional optical microscope to implement the QPI imaging of e.g.,Polymethyl Methacrylate(PMMA)microspheres,microlens arrays and staphylococcus section. The relative error of phase experimentally measured is about 1.8%,proving that the method has a high precision of phase measurement. The experimental results also show that the method can be used for quantitative phase imaging with a wide-spectrum light source,making it easily combined with conventional optical microscopes to have a great application potential in biomedicine,three-dimensional topography measurement and other related fields.
来源 光子学报 ,2022,51(11):1118001 【核心库】
DOI 10.3788/gzxb20225111.1118001
关键词 干涉术 ; 四波横向剪切干涉 ; 定量相位成像 ; 相位测量 ; 相位光栅
地址

1. 中国科学院西安光学精密机械研究所, 瞬态光学与光子技术国家重点实验室, 西安, 710119  

2. 中国科学院大学, 北京, 100049

语种 中文
文献类型 研究性论文
ISSN 1004-4213
学科 物理学
基金 国家自然科学基金 ;  中国科学院青年创新促进会项目 ;  国家重点研发计划重点专项
文献收藏号 CSCD:7358007

参考文献 共 16 共1页

1.  Toto-Arellano N. Phase shifts in the Fourier spectra of phase grating and phase grids:an application for one-shot phase-shifting interferometry. Optics Express,2008,16(23):19330-19341 CSCD被引 4    
2.  Kemper B. Simplified approach for quantitative digital holographic phase contrast imaging of living cells. Journal of Biomedical Optics,2011,16(2):026014 CSCD被引 6    
3.  Belanger E. Comparative study of quantitative phase imaging techniques for refractometry of optical waveguides. Optics Express,2018,26(13):17498-17511 CSCD被引 3    
4.  Gao P. Parallel two-step phase-shifting digital holograph microscopy based on a grating pair. Journal of the Optical Society of America A,2011,28(3):434-440 CSCD被引 10    
5.  Bhaduri B. Diffraction phase microscopy:principles and applications in materials and life sciences. Advanced in Optics and Photonics,2014,6:57-119 CSCD被引 1    
6.  Jafarfard M R. Dual-wavelength diffraction phase microscopy for simultaneous measurement of refractive index and thickness. Optics Letters,2014,39(10):2908-2911 CSCD被引 5    
7.  Anand A. Quantitative cell imaging using single beam phase retrieval method. Journal of Biomedical Optics,2011,16(6):060503 CSCD被引 3    
8.  Fienup J R. Phase retrieval algorithms:a comparison. Applied Optics,1982,21(15):2758-2769 CSCD被引 313    
9.  Petruccelli J C. The transport of intensity equation for optical path length recovery using partially coherent illumination. Optics Express,2013,21(12):14430-14441 CSCD被引 13    
10.  Hasegawa M. Recent progress of EUV wavefront metrology in EUVA. Proceeding of SPIE,The International Society for Optical Engineering. 5533,2004:27-36 CSCD被引 1    
11.  Kato S. Comparison of EUV interferometry methods in EUVA project. Proceeding of SPIE,The International Society for Optical Engineering. 5751,2005:110-117 CSCD被引 1    
12.  Primot J. Extended Hartmann test based on the pseudoguiding property of a Hartmann mask completed by a phase chessboard. Applied Optics,2000,39(31):5715-5720 CSCD被引 13    
13.  Bon P. Quadriwave lateral shearing interferometry for quantitative phase microscopy of living cells. Optics Express,2009,17(15):13080-13094 CSCD被引 15    
14.  Ling T. Quadriwave lateral shearing interferometer based on a randomly encoded hybrid grating. Optics Letters,2015,40(10):2245-2248 CSCD被引 10    
15.  梁瑞生. 信息光学. (2版),2008:74-76 CSCD被引 1    
16.  Kottler C. A two-directional approach for grating based differential phase contrast imaging using hard X-rays. Optics Express,2007,15(3):1175-1181 CSCD被引 9    
引证文献 2

1 袁训禹 基于菱形高斯组合窗滤波的四波横向剪切干涉相位重建 光电子·激光,2024,35(8):844-850
CSCD被引 0 次

2 董正琼 基于四波横向剪切干涉的表面形貌测量方法 激光技术,2024,48(6):906-912
CSCD被引 0 次

显示所有2篇文献

论文科学数据集
PlumX Metrics
相关文献

 作者相关
 关键词相关
 参考文献相关

版权所有 ©2008 中国科学院文献情报中心 制作维护:中国科学院文献情报中心
地址:北京中关村北四环西路33号 邮政编码:100190 联系电话:(010)82627496 E-mail:cscd@mail.las.ac.cn 京ICP备05002861号-4 | 京公网安备11010802043238号