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Items: 1 to 20 of 417

1.
2.

Digital holographic testing of biconvex lenses.

Chhaniwal VK, Kihiko JM, Dubey S, Shearon G, Javidi B, Anand A.

Appl Opt. 2013 Dec 20;52(36):8714-22. doi: 10.1364/AO.52.008714.

PMID:
24513936
3.

Determination of refractive indices of biconvex lenses by use of a Michelson interferometer.

Chhaniwal VK, Anand A, Narayanamurthy CS.

Appl Opt. 2006 Jun 10;45(17):3985-90.

PMID:
16761036
4.

Technique for the focal-length measurement of positive lenses using Fizeau interferometry.

Kumar YP, Chatterjee S.

Appl Opt. 2009 Feb 1;48(4):730-6.

PMID:
19183601
5.

Measurement of low-derivative surface lenses by two-laser holography with Bi12TiO20 crystals.

Barbosa EA, de Sousa CB, Maffei WM.

Appl Opt. 2009 Sep 20;48(27):5114-20. doi: 10.1364/AO.48.005114.

PMID:
19767927
6.

Digital holographic microscopy with physical phase compensation.

Weijuan Q, Yingjie Y, Choo CO, Asundi A.

Opt Lett. 2009 Apr 15;34(8):1276-8.

PMID:
19370142
7.

Focal-length measurement by multiple-beam shearing interferometry.

Matsuda K, Barnes TH, Oreb BF, Sheppard CJ.

Appl Opt. 1999 Jun 1;38(16):3542-8.

PMID:
18319955
9.

Quasi-physical phase compensation in digital holographic microscopy.

Qu W, Choo CO, Singh VR, Yingjie Y, Asundi A.

J Opt Soc Am A Opt Image Sci Vis. 2009 Sep;26(9):2005-11. Erratum in: J Opt Soc Am A Opt Image Sci Vis. 2010 Jul 1;27(7):1660.

PMID:
19721686
10.

Long-term lens organ culture system with a method for monitoring lens optical quality.

Dovrat A, Sivak JG.

Photochem Photobiol. 2005 May-Jun;81(3):502-5.

PMID:
15689176
11.

Compensation of the inherent wave front curvature in digital holographic coherent microscopy for quantitative phase-contrast imaging.

Ferraro P, De Nicola S, Finizio A, Coppola G, Grilli S, Magro C, Pierattini G.

Appl Opt. 2003 Apr 10;42(11):1938-46.

PMID:
12699340
12.

Modeling microlenses by use of vectorial field rays and diffraction integrals.

Alvarez-Cabanillas MA, Xu F, Fainman Y.

Appl Opt. 2004 Apr 10;43(11):2242-50.

PMID:
15098825
13.

Measuring optical properties of an eye lens using magnetic resonance imaging.

Jones CE, Pope JM.

Magn Reson Imaging. 2004 Feb;22(2):211-20.

PMID:
15010113
14.
15.

Transformation of waist parameters of a Gaussian beam by a thick lens.

Nemoto S.

Appl Opt. 1990 Feb 20;29(6):809-16. doi: 10.1364/AO.29.000809.

PMID:
20556188
16.

Discretely tunable optofluidic compound microlenses.

Fei P, He Z, Zheng C, Chen T, Men Y, Huang Y.

Lab Chip. 2011 Sep 7;11(17):2835-41. doi: 10.1039/c1lc20425d.

PMID:
21799999
17.

Single-shot digital holography by use of the fractional Talbot effect.

Martínez-León L, Araiza-E M, Javidi B, Andrés P, Climent V, Lancis J, Tajahuerce E.

Opt Express. 2009 Jul 20;17(15):12900-9.

PMID:
19654695
18.

Alternative method for measuring effective focal length of lenses using the front and back surface reflections from a reference plate.

Kim DH, Shi D, Ilev IK.

Appl Opt. 2011 Sep 10;50(26):5163-8. doi: 10.1364/AO.50.005163.

PMID:
21946999
19.

Alternative method for measuring the full-field refractive index of a gradient-index lens with normal incidence heterodyne interferometry.

Chen YL, Hsieh HC, Wu WT, Chang WY, Su DC.

Appl Opt. 2010 Dec 20;49(36):6888-92. doi: 10.1364/AO.49.006888.

PMID:
21173822
20.

Tunable two-dimensional liquid gradient refractive index (L-GRIN) lens for variable light focusing.

Huang H, Mao X, Lin SC, Kiraly B, Huang Y, Huang TJ.

Lab Chip. 2010 Sep 21;10(18):2387-93. doi: 10.1039/c005071g.

PMID:
20697662
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