Biomedical Engineering Reference
In-Depth Information
[6] K. Kirschfeld, The resolution of lens and compound eyes,
in Neural principles in vision (F. Zettler and R. Weiler, eds.),
Springer-Verlag, New York, NY, USA (1976), 354-370.
[7] E. Hecht, Optics , 4th ed., Addison-Wesley, San Fran-
cisco, CA, USA (2002).
[8] W.J. Smith, Modern optical engineering , 2nd ed., McGraw-
Hill, New York, NY, USA (1990).
[9] C.L. Wyatt, Electro-optical system design , McGraw-Hill,
New York, NY, USA (1991).
[10] J.W. Goodman, Introduction to Fourier optics , 2nd ed.,
McGraw-Hill, New York, NY, USA (1996).
[11] R.G. Wilson, Fourier series and optical transform tech-
niques in contemporary optics , Wiley, New York, NY, USA
(1995).
[12] G.C. Holst, Imaging system performance based upon
F λ/ d , Opt Eng 46 (2007), 103204.
[13] G.C. Holst, Imaging system fundamentals, Opt Eng 50
(2011), 052601.
[14] J. Nakamura, Image sensors and signal processing for digital
still cameras , CRC Press, Boca Raton, FL, USA (2006).
[15] R.H. Vollmerhausen, D.A. Reago, Jr., and R.G. Driggers,
Analysis and evaluation of sampled imaging systems , SPIE
Press, Bellingham, WA, USA (2010).
[16] G.C. Holst, Electro-optical imaging system performance ,
3rd ed., SPIE Press, Bellingham, WA, USA (2003).
[17] B.E.A. Saleh and M.C. Teich, Fundamentals of photonics ,
Wiley, New York, NY, USA (1991).
[18] R.C. Gonzalez and R.E. Woods, Digital image processing ,
3rd ed., Prentice-Hall, Upper Saddle River, NJ, USA
(2008).
[19] R.N. Bracewell, The Fourier transform and its applications ,
3rd ed., McGraw-Hill, New York, NY, USA (2000).
[20] N. van Hulst, Many photons get more out of diffraction,
OSA optics and photonics focus , vol. 4, Story 1. http://www.
opfocus.org/index.php?topic = volume&v = 4 (accessed
10 April 2013).
[21] M. Bass, E.W. van Stryland, D.R. Williams, and
W.L. Wolfe (eds.), Handbook of optics, 2nd ed., vol. 1,
McGraw-Hill, New York, NY, USA (1995).
[22] V. Ronchi, Optics: the science of vision , Dover, New York,
NY, USA (1991).
[23] M. Zghal, H.-E. Bouali, Z.B. Lakhdar, and H. Hamam,
The first steps for learning optics: Ibn Sahl's, Al-Hay-
tham's and Young's works on refraction as typical
examples, Proceedings of the 10th SPIE conference on edu-
cation and training in optics and photonics . http://spie.
org/etop/etop2007.html (accessed 10 April 2013).
[24] J.W. Coltman, The specification of imaging properties
by response to a sine wave target, J Opt Soc Am 44
(1954), 468-471.
[25] A.D. Ducharme and S.P. Temple, Improved aperture for
modulation transfer function measurement of detector
arrays beyond the Nyquist frequency, Opt Eng 47
(2008), 093601.
[26] M. Unser, Sampling—50 years after Shannon, Proc IEEE
88 (2000), 569-587.
[27] C.E. Shannon, A mathematical theory of communica-
tion, Bell Syst Tech J 27 (1948), 623-656.
[28] M.F. Land and R.D. Fernald, The evolution of eyes,
Annu Rev Neurosci 15 (1992), 1-29.
[29] W.F. Ganong, Review of medical physiology , 16th ed.,
Appleton & Lange, Norwalk, CT, USA (1993).
[30] D.G. Vaughan, T. Asbury, and P. Riordan-Eva, General
ophthalmology , 13th ed., Appleton & Lange, Norwalk,
CT, USA (1992).
[31] Y. LeGrand and S.G. El Hage, Physiological optics ,
Springer-Verlag, New York, NY, USA (1980).
[32] R. Sekuler and R. Blake, Perception , 3rd ed., McGraw-
Hill, New York, NY, USA (1994).
[33] H.A. Quigley, A.E. Brown, J.D. Morrison, and
S.M. Drance, The size and shape of the optic disk in
normal human eyes, Arch Ophthalmol 108 (1990), 51-57.
[34] A.M. Mansour, Measuring fundus landmarks, Invest
Ophthalmol Vis Sci 31 (1990), 41-42.
[35] N. Drasdo and C.W. Fowler, Non-linear projection of
the retinal image in a wide-angle schematic eye, Brit J
Ophthalmol 58 (1974), 709-714.
[36] M.F. Land, Visual acuity in insects, Annu Rev Entomol
42 (1997), 147-177.
[37] D.T. Riley, W.M. Harmann, S.F. Barrett, and
C.H.G. Wright, Musca domestica inspired machine vision
sensor with hyperacuity, Bioinsp Biomim 3 (2008), 026003.
[38] J.D. Davis, S.F. Barrett, C.H.G. Wright, and M.J. Wilcox,
A bio-inspired apposition compound eye machine
vision sensor system, Bioinsp Biomim 4 (2009), 046002.
[39] R.S. Prabhakara, C.H.G. Wright, and S.F. Barrett,
Motion detection: a biomimetic vision sensor versus a
CCD camera sensor, IEEE Sens J 12 (2012), 298-307.
[40] G.P. Luke, C.H.G. Wright, and S.F. Barrett, A multi-
aperture bio-inspired sensor with hyperacuity, IEEE
Sens J 12 (2012), 308-314.
[41] G.A. Mazokhin-Porshnyakov, Insect vision , Plenum
Press, New York, NY, USA (1969).
[42] M.F. Land, Optics and vision in invertebrates, in Hand-
topic of sensory physiology , vol. VII/6B (H. Autrum, ed.),
Springer-Verlag, New York, NY, USA (1981), 472-592.
[43] K. Nakayama, Biological image motion processing: a
review, Vision Res 25 (1985), 625-660.
[44] H.B. Barlow, Summation and inhibition in the frog's
retina, J Physiol 199 (1953), 69-88.
[45] J.Y. Lettvin, R. Maturana, W.S. McCulloch, and
W.H. Pitts, What the frog's eye tells the frog's brain,
Proc Inst Radiat Eng 47 (1959), 1940-1951.
[46] D.H. Hubel and T.N. Weisel, Brain mechanisms of
vision, Sci Am 241 (3) (March 1979), 150-162.
[47] K. Nakayama and J.M. Loomis, Optical velocity pat-
terns velocity sensitive neurons, and space perception:
a hypothesis, Perception 3 (1974), 63-80.
Search WWH ::




Custom Search