Simultaneous quantification of longitudinal and transverse ocular chromatic aberrations with Hartmann–Shack wavefront sensor
Yangchun Deng, Junlei Zhao, Yun Dai, Yudong Zhang. Simultaneous quantification of longitudinal and transverse ocular chromatic aberrations with Hartmann–Shack wavefront sensor[J]. Journal of Innovative Optical Health Sciences, 2018, 11(4): 1850021.
[1] J. Liang, D. R. Williams, D. T. Miller, “Supernormal vision and high-resolution retinal imaging through adaptive optics," J. Opt. Soc. Am. A 14(11), 2884–2892 (1997).
[2] F. Reinholz, R. A. Ashman, R. H. Eikelboom, “Simultaneous three wavelength imaging with a scanning laser ophthalmoscope," Cytometry 37(3), 165–170 (1999).
[3] K. Grieve, P. Tiruveedhula, Y. Zhang, A. Roorda, “Multi-wavelength imaging with the adaptive optics scanning laser ophthalmoscope," Opt. Express 14(25), 12230–12242 (2006).
[4] W. M. Harmening, P. Tiruveedhula, A. Roorda, “Measurement and correction of transverse chromatic offsets for multi-wavelength retinal microscopy in the living eye," Biomed. Opt. Express 3(9), 2066–2077 (2012).
[5] K. Ohnuma, H. Kayanuma, T. Lawu, K. Negishi, T. Yamaguchi, T. Noda, “Retinal image contrast obtained by a model eye with combined correction of chromatic and spherical aberrations," Biomed. Opt. Express 2(6), 1443–1457 (2011).
[6] P. Perez-Merino, C. Dorronsoro, L. Llorente, S. Duran, I. Jimenez-Alfaro, S. Marcos, “In vivo chromatic aberration in eyes implanted with intraocular lenses," Invest. Ophthalmol. Vis. Sci. 54(4), 2654–2661 (2013).
[7] M. Nakajima, T. Hiraoka, T. Yamamoto, S. Takagi, Y. Hirohara, T. Oshika, T. Mihashi, “Differences of longitudinal chromatic aberration (LCA) between eyes with intraocular lenses from different manufacturers," PLoS ONE 11(6), e0156227 (2016).
[8] M. Vinas, C. Dorronsoro, N. Garzon, F. Poyales, S. Marcos, “In vivo subjective and objective longitudinal chromatic aberration after bilateral implantation of the same design of hydrophobic and hydrophilic intraocular lenses," J. Cataract. Refract. Surg. 41(10), 2115–2124 (2015).
[9] M. A. Gil et al., “Comparison of far and near contrast sensitivity in patients symmetrically implanted with multifocal and monofocal IOLs," Eur. J. Ophthalmol. 24(1), 44–52 (2013).
[10] W. W. Hutz, R. Jackel, P. C. Hoffman, “Comparison of visual performance of silicone and acrylic multifocal IOLs utilizing the same diffractive design," Acta Ophthalmol. 90(6), 530–533 (2012).
[11] G. Wald, D. R. Gri±n, “The change in refractive power of the human eye in dim and bright light," J. Opt. Soc. Am. 37(5), 321–336 (1947).
[12] M. C. Rynders, R. Navarro, M. A. Losada, “Objective measurement of the off-axis longitudinal chromatic aberration in the human eye," Vis. Res. 38(4), 513–522 (1998).
[13] S. Marcos, S. A. Burns, E. Moreno-Barriusop, R. Navarro, “A new approach to the study of ocular chromatic aberrations," Vis. Res. 39(26), 4309–4323 (1999).
[14] E. Fernandez, A. Unterhuber, P. Prieto, B. Hermann, W. Drexler, P. Artal, “Ocular aberrations as a function of wavelength in the near infrared measured with a femtosecond laser," Opt. Express 13(2), 400–409 (2005).
[15] S. Manzanera, C. Canovas, P. M. Prieto, P. Artal, “A wavelength tunable wavefront sensor for the human eye," Opt. Express 16(11), 7748–7755 (2008).
[16] P. M. Prieto, F. Vargas-Martin, S. Goelz, P. Artal, “Analysis of the performance of the Hartmann–Shack sensor in the human eye," J. Opt. Soc. Am. A 17, 1388–1398 (2000).
[17] J. Liang, B. Grimm, S. Goelz, J. F. Bille, “Objective measurement of wave aberrations of the human eye with the use of a Hartmann–Shack wavefront sensor," J. Opt. Soc. Am. A 11(7), 1949–1957 (1994).
[18] M. Vinas, C. Dorronsoro, D. Cortes, D. Pascual, S. Marcos, “Longitudinal chromatic aberration of the human eye in the visible and near infrared from wavefront sensing, double-pass and psychophysics," Biomed. Opt. Express 6(3), 948–962 (2015).
[19] J. Otero-Millan, X. G. Troncoso, S. L. Macknik, I. Serrano-Pedraza, S. Martinez-Conde, “Saccades and microsaccades during visual fixation, exploration, and search: Foundations for a common saccadic generator," J. Vis. 8(14), 21-1–21-18 (2008).
[20] S. Martinez-Conde, S. L. Macknik, “Fixational eye movements across vertebrates: Comparative dynamics, physiology, and perception," J. Vis. 8(14), 28-1–28-16 (2008).
[21] B. Jaeken, L. Lundstr€om, P. Artal, “Peripheral aberrations in the human eye for different wavelengths: off-axis chromatic aberration," J. Opt. Soc. Am. A 28(9), 1871–1879 (2011).
[22] H. Hartridge, “The visual perception of fine detail," Philos. Trans. R. Soc. B, Biol. Sci. 232, 519–671 (1947).
[23] Y. U. Ogboso, H. E. Bedell, “Magnitude of lateral chromatic aberration across the retina of the human eye," J. Opt. Soc. Am. A 4(8), 1666–1672 (1987).
[24] M. Rynders, B. Lidkea, W. Chisholm, “Statistical distribution of foveal transverse chromatic aberration, pupil centration, and angle in a population of young adult eyes," J. Opt. Soc. Am. A 12(10), 2348–2357 (1995).
[25] L. Lundstr€om et al., “Effect of optical correction and remaining aberrations on peripheral resolution acuity in the human eye," Opt. Express 15(20), 12654–12661 (2007).
[26] S. Martinez-Conde, S. L. Macknik, X. G. Troncoso, D. H. Hubel, “Microsaccades: A neurophysiological analysis," Trends Neurosci. 32(9), 463–475 (2009).
[27] S. Winter et al., “Transverse chromatic aberration across the visual field of the human eye," J. Vis. 16(14), 9 (2016).
[28] J. S. McLellan, S. Marcos, P. M. Prieto, S. A. Burns, “Imperfect optics may be the eye's defence against chromatic blur," Nature 417(9), 174–176 (2002).
[29] L. N. Thibos, A. Bradley, D. L. Still, X. Zhang, P. A. Howarth, “Theory and measurement of ocular chromatic aberration," Vis. Res. 30(1), 33–49 (1990).
[30] G. M. Dai, Ocular wavefront sensing and reconstruction, Wavefront Optics for Vision Correction, pp. 97–119, SPIE Press, Bellingham (2008).
[31] J. Nam, J. Rubinstein, L. Thibos, “Wavelength adjustment using an eye model from aberrometry data," J. Opt. Soc. Am. A 27(7), 1561–1574 (2010).
[32] P. Artal, S. Marcos, D. R. Williams, R. Navarro, “Odd aberrations and double-pass measurements of retinal image quality," J. Opt. Soc. Am. A 12(2), 195–201 (1995).
[33] A. Guirao, N. Lopez-Gil, P. Artal, Double-pass measurements of retinal image quality: A review of the theory, limitations and results, Proc. 2000 Conf. Vision Science and its Applications, Optical Society of America, Washington, DC (2000).
[34] P. Artal, I. C. Iglesias, N. Lopez-Gil, “Double pass system with unequal entrance and exit pupil sizes to measure the optical transfer function of the human eye," Proc. SPIE 2632, 56–61 (1996).
[35] Laser Institute of America, ANSI Standard Z136.1: American National Standard for the Safe Use of Lasers (2014).
[36] D. R. Neal, J. Copland, D. A. Neal, “Shack-Hartmann wavefront sensor precision and accuracy," Proc. SPIE 4779, 148–160 (2002).
[37] L. N. Thibos, M. Ye, X. Zhang, A. Bradley, “The chromatic eye: A new reduced-eye model of ocular chromatic aberration in humans," Appl. Opt. 31(19), 3594–3600 (1992).
[38] D. A. Atchison, G. Smith, “Chromatic dispersions of the ocular media of human eyes," J. Opt. Soc. Am. A 22(1), 29–37 (2005).
Yangchun Deng, Junlei Zhao, Yun Dai, Yudong Zhang. Simultaneous quantification of longitudinal and transverse ocular chromatic aberrations with Hartmann–Shack wavefront sensor[J]. Journal of Innovative Optical Health Sciences, 2018, 11(4): 1850021.