參考文獻 |
[1] D. M. Alloin and J.-M. Mariotti ed., Adaptive Optics for Astronomy, Kluwer Academic, 1994.
[2] S. R. Restaino, W. Junor, and N. Duric ed., Catching the Perfect Wave: Adaptive Optics and Interferometry in the 21st Century, Astronomical Society of the Pacific Conference, 1999.
[3] F. Roddier ed., Adaptive Optics in Astronmy, Cambridge University Press, 1999.
[4] R. K. Tyson, Principles of Adaptive Optics, 2nd Ed., Academic Press, 1998.
[5] D. G. Crowe, Adaptive Optics and Speckle Imaging, SPIE Press, 1994.
[6] S.-J. Chen and J. S. Gibson, “Feedforward adaptive noise control with multivariable gradient lattice filters,” IEEE transactions on signal processing, 49(3), 511-520, 2001.
[7] R. Q. Fugate, J. F. Riker, J. T. Roark, S. Stogsdill, and B. D. O’Neil, “Laser beacon compensated images of Saturn using a high-speed, near-infrared correlation tracker,” in ESO Conference and Workshop Proceedings on Active and Adaptive Optics, edited by M. Cullum (European Southern Observatory, Garching, Germany), 54, 287–290, 1996.
[8] P. R. McCullough, R. Q. Fugate, J. C. Christou, B. L. Ellerbroek, C. H. Higgins, J. M. Spinhirne, R. A. Cleis, and J. F. Moroney, ‘‘Photoevaporating stellar envelopes observed with Rayleigh beacon adaptive optics,’’ Astrophys. J., 438, 394–403, 1995.
[9] H. B. Rosenstock, J. H. Hancock, “Light propagation through a moving gas,” Appl. Opt., 10(6), 1299-1307, 1971.
[10] F. G. Gebhardt, “High power laser propagation,” Appl. Opt. 15(6), 1479-1493, 1976.
[11] R. K. Tyson, “Adaptive optics and ground-to-space laser communications” Appl. Opt., 35(19), 3640-3646, 1996.
[12] E. J. Fernndez, I. Iglesias, and P. Artal, “Closed-loop adaptive optics in the human eye,” Opt. Lett., 26(10), 746-748, 2001.
[13] H. W. Babcock, “The possibility of compensating astronomical seeing,” Publ. Astron. Soc. Pac., 65, 229, 1953.
[14] L. C. Bradley, J. Herrmann, “Phase compensation for thermal blooming,” Appl. Opt., 13(2), 331-334, 1974.
[15] M. C. Roggemann and B. Welsh, Image Through Turbulence, CRC Press, 1996.
[16] F. G. Smith ed., Atmospheric Propagation of Radiation, SPIE, 1993.
[17] J. M. Beckers, “Adaptive optics for astronomy: principles, performance, and applications,” Annu. Rev. Astron. Astrophys., 31, 13–62, 1993.
[18] D. L. Fried, “Anisoplanatism in adaptive optics,” J. Opt. Soc. Am., 72, 52–61, 1982.
[19] B. M. Welsh, and C. S. Gardner, “Effects of turbulence induced anisoplanatism on the imaging performance of adaptive astronomical telescopes using laser guide stars,” J. Opt. Soc. Am. A, 8, 69–80, 1991.
[20] J.-P. Gaffard and G. Ledanois, “Adaptive optical transfer function modeling,” Proc. SPIE, 1542, 34-45, 1991.
[21] A. N. Kolmogorov, “The local structure of turbulence in incompressible viscous fluids for very large Reynolds’ numbers,” in Turbulence, classic papers on statistical theory, 151–155, 1961.
[22] G. D. Boreman and C. Dainty, “Zernike expansions for non-Kolmogorov turbulence,” J. Opt. Soc. Am. A, 13, 517, 1996.
[23] R. R. Parenti and R. J. Sasiela, “Laser-guide-star systems for astronomical applications,” J. Opt. Soc. Am. A, 11, 288–309, 1994.
[24] A. T. Young, “Seeing: Its cause and cure,” Astrophys. J., 189, 587–604, 1974.
[25] A. Ishimaru, Wave Propagation and Scattering in Random Media, Academic, 1978.
[26] L. M. Frantz, A. A. Sawchuk, and W. von der Ohe, “Optical phase measurement in real time,” Appl. Opt. 18(19), 3301-3306, 1979.
[27] S. E. Troxel, B. M. Welsh, and M. C. Roggemann, “Offaxis optical transfer function calculations in an adaptiveoptics system by means of a diffraction calculation for weak index fluctuations,” J. Opt. Soc. Am. A, 11, 2100–2111, 1994.
[28] D. L. Fried, “Optical resolution through a randomly inhomogeneous medium for very long and very short exposures,” J. Opt. Soc. Am., 56, 1372–1379, 1966.
[29] J. W. Goodman, Statistical Optics, Wiley, 1985.
[30] D. C. Smith, “High-power laser propagation: thermal blooming,” IEEE J. Quant. Electro., 5, 1679, 1969.
[31] L. C. Bradley, J. Herrmann, and J. Herrmann, ”Phase compensation for thermal blooming,” Appl. Opt., 13, 331, 1974.
[32] J.-N. Juang, Appied System Identification, Prentice Hall, 1994.
[33] Lennart Ljung, System Identification Toolbox for Use with MATLAB, Mathworks, 2001.
[34] S.-K. Park, S.-H. Baik, C.-J. Kim, and S. W. Ra, “A study on a fast measuring technique of wavefront using a Shack–Hartmann sensor,” Optics & Laser Technology, 34, 687-694, 2002.
[35] D. B. Dayton, B. Pierson, Spielbusch, and J. Gonglewski, “Atmospheric structure function measurements with a Shack-Hartmann wave-front sensor,” Opt. Lett., 17, 1737–1739, 1992.
[36] G. Harbers, P. J. Kunst, and G. W. R. Leibbrandt, “Analysis of lateral shearing interferograms by use of Zernike polynomials,” Appl. Opt., 35(31), 6162-6172, 1996.
[37] M. P. Rimmer, “Method for Evaluating Lateral Shearing Interferograms,” Appl. Opt., 13(3), 623-629, 1974.
[38] C. Elster, “Exact wave-front reconstruction from two lateral shearing interferograms,” J. Opt. Soc. Am. A, 16(9), 2281-2285, 1999.
[39] H.-H. Lee, J.-H. You, and S.-H. Park, “Phase-shifting lateral shearing interferometer with two pairs of wedge plates”, Opt. Lett., 28(22), 2243-2245, 2003.
[40] F.Roddier, C. Roddier, and N. Roddier, “Curvature sensing: a new wavefront sensing method,” SPIE Proc., 976, 203–209, 1988..
[41] G. Rousset, “Wavefront sensing,” in Adaptive Optics for Astronomy, edited by D. M. Alloin and J.-M. Mariotti ,Kluwer Academic, 115–137, 1994.
[42] D. W. Griffin, “Phase-shifting shearing interferometer,” Opt. Lett. 26, 140-141, 2001.
[43] D. Malacara, Optical Shop Testing, Wiley, 1992.
[44] D. Malacara, M. Servin, and Z. Malacara, Interferogram Analysis for Optical Testing, Marcel Dekker, 1998.
[45] 邱銘宏,共光程外差干涉儀的原理與其應用之研究,交通大學光電工程所博士論文,1997。
[46] B. V. Dorrío and J. L. Fernández, “Phase-evaluation methods in whole-field optical measurement techniques,” Meas. Sci. Technol., 10(3), 33-55, 1999.
[47] R. M. Goldstein, H. A. Zebker, and C. L. Werner, “Satellite radar interferometry: two-dimensional phase unwrapping,” Radio Science, 23(4), 713-720, 1988.
[48] D.C. Ghiglia and M.D. Pritt, Two-dimensional Phase Unwrapping: Theory, Algorithms and Software, John Wiley & Sons, Inc. 1998.
[49] J. M. Huntley, “Noise-immune phase unwrapping algorithm,” Appl. Opt., 28(15), 3268-3270, 1989.
[50] R. Cusack, J. M. Huntley, and H. T. Goldrein, “Improved noise-immune phase-unwrapping algorithm,” Appl. Opt., 34(5), 781-789, 1995.
[51] J. R. Buckland, J. M. Huntley, and S. T. E. Turner, “Unwrapping noisy phase maps by use of a minimum cost matching algorithm,” Appl. Opt., 34(23), 5100-5108, 1995.
[52] D. J. Bone, “Fourier fringe analysis: the Two-dimensional phase unwrapping problem,” Appl. Opt., 30(25), 3627-3632, 1991.
[53] Y. Xu and C. Ai, “Simple and effective phase unwrapping technique,” SPIE Proc., 2003, 254-263, 1993.
[54] J. A. Quiroga, A. Gonz’alez-Cano, and E. Bernabeu, “Phase-unwrapping algorithm based on an adaptive criterion,” Appl. Opt., 34(14), 2560-2563, 1995.
[55] H. Lim, W. Xu, and X. Huang, “Two new practical methods for phase unwrapping,” Proceedings of the International Geoscience and Remote Sensing Symposium, (Tokyo, Japan), 196-198, 1995.
[56] D. Derauw, “Phase unwrapping using coherence measurements,” Synthetic Aperture Radar and Passive Microwave Sensing, SPIE Proc., 2584, 319-324, 1995.
[57] http://www.analog.com
[58] http://www.meadowlark.com
[59] http://www.meadowlark.com/catalog/LiquidCrystals/liqcrys1.htm
[60] M. A. Vorontsov and G. W. Carhart, “Adaptive phase-distortion correction based on parallel gradient-descent optimization,” Opt. Lett., 22(12),907-909, 1997.
[61] T. G. Bifano, J. Perreault, R. K. Mali, and M. N. Horenstein, “Microelectromechanical deformable mirrors,” IEEE J. Quant. Electro., 5(1), 83-89, 1999.
[62] M. Horenstein, T. Bifano, R. K. Mali, and N. Vandelli, “Electrostatic effects in micromachined actuators for adaptive optics,” J. Electrostat., 42, 1–2, 1997.
[63] http://www.intellite.com |