Literature DB >> 19471373

Benefit of higher closed-loop bandwidths in ocular adaptive optics.

Luis Diaz-Santana, Cristiano Torti, Ian Munro, Paul Gasson, Chris Dainty.   

Abstract

We present an ocular adaptive optics system with a wavefront sampling rate of 240 Hz and maximum recorded closed-loop bandwidth close to 25 Hz, but with typical performances around 10 Hz. The measured bandwidth depended on the specific system configuration and the particular subject tested. An analysis of the system performance as a function of achieved bandwidth showed consistently higher Strehl ratios for higher closed-loop bandwidths. This may be attributed to a combination of limitations on the available technology and the dynamics of ocular aberrations. We observed dynamic behaviour with a maximum frequency content around 30 Hz.

Entities:  

Year:  2003        PMID: 19471373     DOI: 10.1364/oe.11.002597

Source DB:  PubMed          Journal:  Opt Express        ISSN: 1094-4087            Impact factor:   3.894


  20 in total

1.  High-speed adaptive optics for imaging of the living human eye.

Authors:  Yongxin Yu; Tianjiao Zhang; Alexander Meadway; Xiaolin Wang; Yuhua Zhang
Journal:  Opt Express       Date:  2015-09-07       Impact factor: 3.894

2.  Requirements for discrete actuator and segmented wavefront correctors for aberration compensation in two large populations of human eyes.

Authors:  Nathan Doble; Donald T Miller; Geunyoung Yoon; David R Williams
Journal:  Appl Opt       Date:  2007-07-10       Impact factor: 1.980

3.  Optical quality of the eye degraded by time-varying wavefront aberrations with tear film dynamics.

Authors:  Yoko Hirohara; Toshifumi Mihashi; Shizuka Koh; Sayuri Ninomiya; Naoyuki Maeda; Takashi Fujikado
Journal:  Jpn J Ophthalmol       Date:  2007-08-03       Impact factor: 2.447

4.  Adaptive-optics optical coherence tomography for high-resolution and high-speed 3D retinal in vivo imaging.

Authors:  Robert J Zawadzki; Steven M Jones; Scot S Olivier; Mingtao Zhao; Bradley A Bower; Joseph A Izatt; Stacey Choi; Sophie Laut; John S Werner
Journal:  Opt Express       Date:  2005-10-17       Impact factor: 3.894

5.  High temporal resolution aberrometry in a 50-eye population and implications for adaptive optics error budget.

Authors:  Jessica Jarosz; Pedro Mecê; Jean-Marc Conan; Cyril Petit; Michel Paques; Serge Meimon
Journal:  Biomed Opt Express       Date:  2017-03-07       Impact factor: 3.732

6.  Influence of wave-front sampling in adaptive optics retinal imaging.

Authors:  Marie Laslandes; Matthias Salas; Christoph K Hitzenberger; Michael Pircher
Journal:  Biomed Opt Express       Date:  2017-01-24       Impact factor: 3.732

7.  Adaptive optics without altering visual perception.

Authors:  D E Koenig; N W Hart; H J Hofer
Journal:  Vision Res       Date:  2014-03-07       Impact factor: 1.886

8.  Increasing the field of view of adaptive optics scanning laser ophthalmoscopy.

Authors:  Marie Laslandes; Matthias Salas; Christoph K Hitzenberger; Michael Pircher
Journal:  Biomed Opt Express       Date:  2017-10-03       Impact factor: 3.732

9.  Adaptive optics optical coherence tomography at 120,000 depth scans/s for non-invasive cellular phenotyping of the living human retina.

Authors:  Cristiano Torti; Boris Povazay; Bernd Hofer; Angelika Unterhuber; Joseph Carroll; Peter Kurt Ahnelt; Wolfgang Drexler
Journal:  Opt Express       Date:  2009-10-26       Impact factor: 3.894

10.  Dual-thread parallel control strategy for ophthalmic adaptive optics.

Authors:  Yongxin Yu; Yuhua Zhang
Journal:  Chin Opt Lett       Date:  2014       Impact factor: 2.448
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