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Items: 1 to 20 of 109

1.
2.

Closed-loop aberration correction by use of a modal Zernike wave-front sensor.

Neil MA, Booth MJ, Wilson T.

Opt Lett. 2000 Aug 1;25(15):1083-5.

PMID:
18064278
3.

Characteristics of a 128 x 128 liquid-crystal spatial light modulator for wave-front generation.

Cho DJ, Thurman ST, Donner JT, Morris GM.

Opt Lett. 1998 Jun 15;23(12):969-71.

PMID:
18087400
4.

Phase-aberration correction with dual liquid-crystal spatial light modulators.

Kelly TL, Munch J.

Appl Opt. 1998 Aug 1;37(22):5184-9.

PMID:
18285994
5.

Adaptive optics with a programmable phase modulator: applications in the human eye.

Prieto P, Fernández E, Manzanera S, Artal P.

Opt Express. 2004 Aug 23;12(17):4059-71.

PMID:
19483947
6.

Real-time optical aberration correction with a ferroelectric liquid-crystal spatial light modulator.

Birch PM, Gourlay J, Love GD, Purvis A.

Appl Opt. 1998 Apr 10;37(11):2164-9.

PMID:
18273139
7.

Adaptive optics with advanced phase-contrast techniques. I. High-resolution wave-front sensing.

Vorontsov MA, Justh EW, Beresnev LA.

J Opt Soc Am A Opt Image Sci Vis. 2001 Jun;18(6):1289-99.

PMID:
11393622
8.

Phase-only liquid crystal spatial light modulator for wavefront correction with high precision.

Hu L, Xuan L, Liu Y, Cao Z, Li D, Mu Q.

Opt Express. 2004 Dec 27;12(26):6403-9.

PMID:
19488289
9.

Adaptive optics using a liquid crystal phase modulator in conjunction with a Shack-Hartmann wave front sensor and zonal control algorithm.

Dayton D, Sandven S, Gonglewski J, Browne S, Rogers S, McDermott S.

Opt Express. 1997 Nov 24;1(11):338-46.

PMID:
19377554
10.

Adaptive wave-front correction by means of all-optical feedback interferometry.

Shirai T, Barnes TH, Haskell TG.

Opt Lett. 2000 Jun 1;25(11):773-5.

PMID:
18064179
11.
12.

Correction of the aberrations in the human eye with a liquid-crystal spatial light modulator: limits to performance.

Vargas-Martín F, Prieto PM, Artal P.

J Opt Soc Am A Opt Image Sci Vis. 1998 Sep;15(9):2552-62.

PMID:
9729868
13.

Binary adaptive optics: atmospheric wave-front correction with a half-wave phase shifter.

Love GD, Andrews N, Birch P, Buscher D, Doel P, Dunlop C, Major J, Myers R, Purvis A, Sharples R, Vick A, Zadrozny A, Restaino SR, Glindemann A.

Appl Opt. 1995 Sep 20;34(27):6058-66. doi: 10.1364/AO.34.006058.

PMID:
21060444
14.

Active aberration correction for the writing of three-dimensional optical memory devices.

Neil MA, Juskaitis R, Booth MJ, Wilson T, Tanaka T, Kawata S.

Appl Opt. 2002 Mar 1;41(7):1374-9.

PMID:
11902148
15.

Nearly diffraction-limited laser focal spot obtained by use of an optically addressed light valve in an adaptive-optics loop.

Chanteloup JC, Baldis H, Migus A, Mourou G, Loiseaux B, Huignard JP.

Opt Lett. 1998 Mar 15;23(6):475-7.

PMID:
18084549
16.

Wave-front generation of Zernike polynomial modes with a micromachined membrane deformable mirror.

Zhu L, Sun PC, Bartsch DU, Freeman WR, Fainman Y.

Appl Opt. 1999 Oct 1;38(28):6019-26.

PMID:
18324122
17.

Performance of a phase-conjugate engine implementing a finite-bit phase correction.

Baker KL, Stappaerts EA, Wilks SC, Gavel D, Young PE, Tucker J, Olivier SS, Silva DA, Olsen J.

Opt Lett. 2004 May 1;29(9):980-2.

PMID:
15143647
18.

Statistical variation of aberration structure and image quality in a normal population of healthy eyes.

Thibos LN, Hong X, Bradley A, Cheng X.

J Opt Soc Am A Opt Image Sci Vis. 2002 Dec;19(12):2329-48.

PMID:
12469728
19.

Spherical aberration correction using a liquid-crystal spatial-light modulator in off-axis electron holography.

Chen J, Hirayama T, Ishizuka K, Tonomura A.

Appl Opt. 1994 Oct 1;33(28):6597-602. doi: 10.1364/AO.33.006597.

PMID:
20941198
20.

Wave-aberration control with a liquid crystal on silicon (LCOS) spatial phase modulator.

Fernández EJ, Prieto PM, Artal P.

Opt Express. 2009 Jun 22;17(13):11013-25.

PMID:
19550501

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