Phase correction and resolution improvement of digital holographic image in numerical reconstruction with angular multiplexing 被引量：1

Phase correction and resolution improvement of digital holographic image in numerical reconstruction with angular multiplexing

原文传递

导出

摘要 A phase correction method is presented to remove the phase slope of the sub-holograms caused by the multi-direction illumination on object in digital holography. To improve the resolution of the reconstructed holographic images, two sub-holograms are recorded by using angular multiplexing and their phase slope parameter is obtained by theoretical analysis. Introducing a phase correction parameter to this phase slope, the ideal complex reconstructed image can be obtained by superposing the reconstructed object wave fields of the two sub-holograms. Experimental results demonstrate that the resolution of the reconstructed image can be effectively enhanced. A phase correction method is presented to remove the phase slope of the sub-holograms caused by the multi-direction illumination on object in digital holography. To improve the resolution of the reconstructed holographic images, two sub-holograms are recorded by using angular multiplexing and their phase slope parameter is obtained by theoretical analysis. Introducing a phase correction parameter to this phase slope, the ideal complex reconstructed image can be obtained by superposing the reconstructed object wave fields of the two sub-holograms. Experimental results demonstrate that the resolution of the reconstructed image can be effectively enhanced.

作者闫晓博赵建林邸江磊姜宏振孙伟伟

机构地区 Institute of Optical Information Science and Technology

出处《Chinese Optics Letters》 SCIE EI CAS CSCD 2009年第12期1072-1075,共4页 中国光学快报（英文版）

基金 supported by the Science Foundation of Aeronautics of China under Grant No. 2006ZD53042

关键词 Computer generated holography MULTIPLEXING Computer generated holography Multiplexing

分类号 TP391.41 [自动化与计算机技术—计算机应用技术] P631.443 [天文地球—地质矿产勘探]

引文网络
相关文献

参考文献16

1J. W. Goodman and R. W. Lawrence, Appl. Phys. Lett. 11, 77 (1967).
2U. Schnars and W. Juptner, Appl. Opt. 33, 179 (1994).
3T.-C. Pooh, Digital Holography and Three-Dimensional Display (Springer, New York, 2006).
4J. Di, J. Zhao, Q. Fan, H. Jiang, and W. Sun, Acta Opt. Sin. (in Chinese) 28, 56 (2008).
5T.-C. Poon, K. B. Doh, B. W. Schilling, M. H. Wu, K. Shinoda, and Y. Suzuki, Opt. Eng. 34, 1338 (1995).
6B. W. Schilling, T.-C. Poon, G. Indebetouw, B. Storrie, K. Shinoda, Y. Suzuki, and M. H. Wu, Opt. Lett. 22, 1506 (1997).
7T. Zhang and I. Yamaguchi, Opt. Lett. 23, 1221 (1998).
8C. Qin, J. Zhao, J. Di, L. Wang, Y. Yu, and W. Yuan, Appl. Opt. 48, 919 (2009).
9J. Zhao, H. Jiang, and J. Di, Opt. Express 16, 2514 (2008).
10Z. Li, F. Xia, G. Zheng, and J. Zhang, Chin. Opt. Lett.6, 251 (2008).

同被引文献13

1钟丽云,张以谟,吕晓旭.合成孔径数字全息的记录、再现及实现[J].中国激光,2004,31(10):1207-1211. 被引量：11
2HILLMAN T R, GUTZLER T, ALEXANDROV S A,et al. High-resolution, wide-field object reconstruction with synthetic aperture Fourier holographic optical microscopy[J]. Optics Express, 2009,17 (10) : 7873-7892.
3YUAN C J, ZHAI H C, LIU H T. Angular multiplexing in pulsed digital holography for aperture synthesis[J]. Optics Letters, 2008, 33(20) :3256-3258.
4FENG P,WEN X, LU R. Long-working-distance synthetic aperture Fresnel off-axis digital holography[J]. Optics Express, 2009,17 (7) : 5473-5480.
5JIANG H Z, ZHAO J L, DI J L, et al. Numerically correcting the joint misplacement of the sub-holograms in spatial synthetic aperture digital Fresnel holography[J]. Optics Express, 2009,17(21): 18836- 18842.
6MASSING J H. Digital off-axis holography with a synthetic aperture[J]. Optics Letters, 2002,27 (24) : 2179- 2181.
7DI J L,ZHAO J L,JIANG H Z,et al. High resolution digital holographic microscopy with a wide field of view based on a synthetic aperture technique and use of linear CCD seanning[J]. Applied Optics, 2008,47(30), 5654-5659.
8CHENG M Y, CHENG W M,WANG C W. Multi-aperture overlap-scanning technique for large aperture test[J]. SPIE, 1991,1553: 626-635.
9OTSUBO M, OKADA K. Measurement of large plane surface shapes by connecting small-aperture interferograms[J]. Opt Eng, 1994, 33(2) :608-613.
10冯忠耀,贾昉,周景会,忽满利.数字全息中利用图像拼接测量大物体的三维形貌[J].中国激光,2008,35(12):2017-2021. 被引量：13

引证文献1

1于瀛洁,郭路,周文静.数字全息位相拼接实验研究[J].光学仪器,2011,33(4):55-59. 被引量：5

二级引证文献5

1毛磊,李勇,马利红,张燕珂.显微数字全息图相位的滤波法提取[J].光学仪器,2012,34(4):16-20. 被引量：2
2韩建,何学兰,魏运峰.基于FPGA的FIR数字滤波器算法的改进及仿真[J].光学仪器,2013,35(5):56-59. 被引量：2
3韩建,何学兰,魏运锋.高速采样及恢复系统的设计与实现[J].光学仪器,2014,36(1):36-39. 被引量：2
4牟海维,田博文,徐佳琦,黄颖.基于AES10光纤总线多功能音频控制系统的研究[J].光学仪器,2014,36(3):234-238.
5李欣芫,赵梓言,付申成.马赫-曾德干涉光路下的全息数字记录及其再现[J].大学物理实验,2018,31(5):17-20.

1耿玉岭,张少岭.利用多次覆盖记录细致提取静校正参数的方法探讨[J].物探与化探,1989,13(2):155-157.
2技术宅.复制PC经验? 微软Windows Holographic解读[J].电脑爱好者,2016,0(15):60-61.
3唐俊龙,方玉标,刘浪,陈建成.数字全息图像处理技术研究[J].电子世界,2014(16):91-92. 被引量：1
4S. McLaughlin,C. Leach,S. Gneiting,V. M. Bove, Jr.,S. Jolly,D. E. Smalley.Progress on waveguide-based holographic video(Invited Paper)[J].Chinese Optics Letters,2016,14(1):7-11.
5曹汉强,朱光喜,朱耀庭,陈汝钧,吴正平.基于数学形态学的数字图像生成及其应用[J].光电子．激光,2003,14(8):855-857.
6杨兴昌,陶世荃.角度复用透射型体全息图的存储容量[J].北京工业大学学报,1997,23(3):73-82.
7杨飞,蔡子亮.掺杂铌酸锂晶体体全息存储的研究[J].科技信息,2008(33):39-39. 被引量：1
8徐万祥,柴本红,侯永平.RTK测量高程精度探讨[J].地矿测绘,2009,25(2):21-23. 被引量：6
9问峰,张荀,袁晨志,李昌彪,王静达,张彦鹏.Visibility and Resolution Enhancement of Fourth-Order Ghost Interference with Thermal Light[J].Chinese Physics Letters,2015,32(1):70-74.
10张三光.关于航天遥感图像分辨率及其野外测定若干问题的探讨[J].测绘科技,1993(4):50-54.

Chinese Optics Letters

2009年第12期

浏览历史

内容加载中请稍等...

Phase correction and resolution improvement of digital holographic image in numerical reconstruction with angular multiplexing 被引量：1

参考文献16

同被引文献13

引证文献1

二级引证文献5

相关作者

相关机构

相关主题

浏览历史