Abstract

This paper discusses modern problems of video informatics in the area of the formation, transmission, processing, analysis, and visualization of video information. The distinguishing feature of video informatics is that it treats these problems from a unified theoretical viewpoint, and this allows the characteristics of video-information systems to be developed and optimized as a unified whole. It is shown to be effective to use a theoretical–informational approach to analyze and optimize video-information systems, starting from the optical channel of radiation propagation in free space when images or multi-dimensional video data are being formed and concluding with the visualization system. Promising directions of further development of the methods of video informatics are highlighted.

© 2012 OSA

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2012

V. M. Bove, “Display holography’s digital second act,” Proc. IEEE 100, 918 (2012).
[CrossRef]

2011

2010

S. S. Gorthi and P. Rastogi, “Fringe projection techniques: whither we are?” Opt. Lasers Eng. 48, 133 (2010).
[CrossRef]

S. Zhang, “Recent progresses on real-time 3D shape measurement using digital fringe-projection techniques,” Opt. Lasers Eng. 48, 149 (2010).
[CrossRef]

P. C. Barnum, S. G. Narasimhan, and T. Kanade, “A multilayered display with water drops,” ACM Trans. Graph. 29, 76 (2010).
[CrossRef]

2008

Y. Bai, J. Bajaj, J. W. Beletic, M. C. Farris, A. Joshi, S. Lauxtermann, A. Petersen, and G. Williams, “Teledyne imaging sensors: silicon CMOS imaging technologies for X-ray, UV, visible and near infrared,” Proc. SPIE 7021, 702102 (2008).
[CrossRef]

A. S. Potapov, “Choosing representations of images based on minimization of the representation length of their description,” Izv. Vyssh. Uchebn. Zaved. Prib. 51, No. 7, 3 (2008).

M. Mackay, R. G. Fenton, and B. Benhabib, “Time-varying-geometry object surveillance using a multi-camera active-vision system,” Int. J. Smart Sens. Intell. Syst. 1, 679 (2008).

2007

A. V. Fantin, A. Albertazzia, and T. L. Pintoa, “An efficient mesh-oriented algorithm for 3D measurement in multiple-camera fringe projection,” Proc. SPIE 6616, 66161 (2007).
[CrossRef]

J. M. Huntley, T. Ogundana, R. L. Burguete, and C. R. Coggrave, “Large-scale full-field metrology using projected fringes: some challenges and solutions,” Proc. SPIE 6616, 66162 (2007).
[CrossRef]

2006

J.-Y. Son, B. Javidi, and K.-D. Kwack, “Methods for displaying three-dimensional images,” Proc. IEEE 94, 502 (2006).
[CrossRef]

Y. Frauel, T. J. Naughton, O. Matoba, E. Tajahuerce, and B. Javidi, “Three-dimensional imaging and processing using computational holographic imaging,” Proc. IEEE 94, 636 (2006).
[CrossRef]

R. Otsuka, T. Hoshino, and Y. Horry, “Transpost: 360-viewable three- dimensional display system,” Proc. IEEE 94, 629 (2006).
[CrossRef]

O. Cakmakci and J. Rolland, “Head-worn displays: a review,” J. Disp. Technol. 2, 199 (2006).
[CrossRef]

2004

S. Suyama, Y. Ishigure, H. Takada, K. Nakazawa, J. Hosohata, Y. Takao, and T. Fujikao, “Apparent 3-D image perceived from luminance-modulated two 2-D images displayed at different depths,” Vision Res. 44, 785 (2004).
[CrossRef]

J. L. Lowrance, V. J. Mastrocola, G. F. Renda, P. K. Swain, R. Kabra, M. Bhaskaran, J. R. Tower, and P. A. Levine, “Ultrahigh-frame CCD imagers,” Proc. SPIE 5210, 521067 (2004).

F. L. Kooi and A. Toet, “Visual comfort of binocular and 3D displays,” Displays 25, 99 (2004).
[CrossRef]

2003

C. Wagner and G. Häusler, “Information theoretical optimization for optical image sensors,” Appl. Opt. 42, 5418 (2003).
[CrossRef] [PubMed]

M. Stanley, R. W. Bannister, C. D. Cameron, S. D. Coomber, I. G. Cresswell, J. R. Hughes, V. Hui, P. O. Jackson, K. A. Milham, R. J. Miller, D. A. Payne, J. Quarrel, D. C. Scattergood, A. P. Smith, M. A. Smith, D. L. Tipton, P. J. Watson, P. J. Webber, and C. W. Slinger, “100-megapixel computer-generated holographic images from active tiling—a dynamic and scalable electro-optic modulator system,” Proc. SPIE 5005, 247 (2003).
[CrossRef]

2001

J. Gruninger, R. L. Sundberg, M. J. Fox, R. Levine, W. F. Mundkowsky, M. S. Salisbury, and A. H. Ratcliff, “Automated optimal channel selection for spectral imaging sensors,” Proc. SPIE 4381, 43811 (2001).

2000

P. M. B. Vitanyi and M. Li, “Minimum description length induction, Bayesianism, and Kolmogorov complexity,” IEEE Trans. Inf. Theory 46, 446 (2000).
[CrossRef]

1997

1995

M. Subbarao and T. S. Choi, “Accurate recovery of three-dimensional shape from image focus,” IEEE Trans. Pattern Anal. Mach. Intell. 17, 266 (1995).
[CrossRef]

1908

G. Lippmann, “La photographie integrale,” C. R. Acad. Sci. 46, 446 (1908).

Albertazzia, A.

A. V. Fantin, A. Albertazzia, and T. L. Pintoa, “An efficient mesh-oriented algorithm for 3D measurement in multiple-camera fringe projection,” Proc. SPIE 6616, 66161 (2007).
[CrossRef]

Arai, J.

Arima, Y.

Bai, Y.

Y. Bai, J. Bajaj, J. W. Beletic, M. C. Farris, A. Joshi, S. Lauxtermann, A. Petersen, and G. Williams, “Teledyne imaging sensors: silicon CMOS imaging technologies for X-ray, UV, visible and near infrared,” Proc. SPIE 7021, 702102 (2008).
[CrossRef]

Bajaj, J.

Y. Bai, J. Bajaj, J. W. Beletic, M. C. Farris, A. Joshi, S. Lauxtermann, A. Petersen, and G. Williams, “Teledyne imaging sensors: silicon CMOS imaging technologies for X-ray, UV, visible and near infrared,” Proc. SPIE 7021, 702102 (2008).
[CrossRef]

Baltiiskii, S. A.

S. A. Balti?ski?, I. P. Gurov, S. De Nikola, D. Koppola, and P. Ferraro, “Modern methods of digital holography,” in Problems of Coherent and Digital Optics, I. P. Gurov and S. A. Kozlov, eds. (SPb GU ITMO, St. Petersburg, 2004), pp. 91–117.

Bannister, R. W.

M. Stanley, R. W. Bannister, C. D. Cameron, S. D. Coomber, I. G. Cresswell, J. R. Hughes, V. Hui, P. O. Jackson, K. A. Milham, R. J. Miller, D. A. Payne, J. Quarrel, D. C. Scattergood, A. P. Smith, M. A. Smith, D. L. Tipton, P. J. Watson, P. J. Webber, and C. W. Slinger, “100-megapixel computer-generated holographic images from active tiling—a dynamic and scalable electro-optic modulator system,” Proc. SPIE 5005, 247 (2003).
[CrossRef]

Barnum, P. C.

P. C. Barnum, S. G. Narasimhan, and T. Kanade, “A multilayered display with water drops,” ACM Trans. Graph. 29, 76 (2010).
[CrossRef]

Beletic, J. W.

Y. Bai, J. Bajaj, J. W. Beletic, M. C. Farris, A. Joshi, S. Lauxtermann, A. Petersen, and G. Williams, “Teledyne imaging sensors: silicon CMOS imaging technologies for X-ray, UV, visible and near infrared,” Proc. SPIE 7021, 702102 (2008).
[CrossRef]

Benhabib, B.

M. Mackay, R. G. Fenton, and B. Benhabib, “Time-varying-geometry object surveillance using a multi-camera active-vision system,” Int. J. Smart Sens. Intell. Syst. 1, 679 (2008).

Bhaskaran, M.

J. L. Lowrance, V. J. Mastrocola, G. F. Renda, P. K. Swain, R. Kabra, M. Bhaskaran, J. R. Tower, and P. A. Levine, “Ultrahigh-frame CCD imagers,” Proc. SPIE 5210, 521067 (2004).

Blaicher, F.

W. Wu, F. Blaicher, J. Yang, T. Seder, and D. Cui, “A prototype of landmark-based car navigation using a full-windshield head-up display system,” in Proceedings of Workshop on Ambient Media Computing, ACM, 2009, pp. 21–28.

Bol’shakov, A. A.

R. N. Karimov and A. A. Bol’shakov, Methods of Processing Multi-Dimensional Data and Time Series (Goryachaya Liniya-Telekom, Moscow, 2007).

Bove, V. M.

V. M. Bove, “Display holography’s digital second act,” Proc. IEEE 100, 918 (2012).
[CrossRef]

Burguete, R. L.

J. M. Huntley, T. Ogundana, R. L. Burguete, and C. R. Coggrave, “Large-scale full-field metrology using projected fringes: some challenges and solutions,” Proc. SPIE 6616, 66162 (2007).
[CrossRef]

Cakmakci, O.

O. Cakmakci and J. Rolland, “Head-worn displays: a review,” J. Disp. Technol. 2, 199 (2006).
[CrossRef]

Cameron, C. D.

M. Stanley, R. W. Bannister, C. D. Cameron, S. D. Coomber, I. G. Cresswell, J. R. Hughes, V. Hui, P. O. Jackson, K. A. Milham, R. J. Miller, D. A. Payne, J. Quarrel, D. C. Scattergood, A. P. Smith, M. A. Smith, D. L. Tipton, P. J. Watson, P. J. Webber, and C. W. Slinger, “100-megapixel computer-generated holographic images from active tiling—a dynamic and scalable electro-optic modulator system,” Proc. SPIE 5005, 247 (2003).
[CrossRef]

Chen, N.

Chobanu, M.

M. Chobanu, Multi-Dimensional Multi-Speed Signal-Processing Systems (Tekhnosfera, Moscow, 2009).

Choi, H.-J.

Choi, T. S.

M. Subbarao and T. S. Choi, “Accurate recovery of three-dimensional shape from image focus,” IEEE Trans. Pattern Anal. Mach. Intell. 17, 266 (1995).
[CrossRef]

Coggrave, C. R.

J. M. Huntley, T. Ogundana, R. L. Burguete, and C. R. Coggrave, “Large-scale full-field metrology using projected fringes: some challenges and solutions,” Proc. SPIE 6616, 66162 (2007).
[CrossRef]

Coomber, S. D.

M. Stanley, R. W. Bannister, C. D. Cameron, S. D. Coomber, I. G. Cresswell, J. R. Hughes, V. Hui, P. O. Jackson, K. A. Milham, R. J. Miller, D. A. Payne, J. Quarrel, D. C. Scattergood, A. P. Smith, M. A. Smith, D. L. Tipton, P. J. Watson, P. J. Webber, and C. W. Slinger, “100-megapixel computer-generated holographic images from active tiling—a dynamic and scalable electro-optic modulator system,” Proc. SPIE 5005, 247 (2003).
[CrossRef]

Cresswell, I. G.

M. Stanley, R. W. Bannister, C. D. Cameron, S. D. Coomber, I. G. Cresswell, J. R. Hughes, V. Hui, P. O. Jackson, K. A. Milham, R. J. Miller, D. A. Payne, J. Quarrel, D. C. Scattergood, A. P. Smith, M. A. Smith, D. L. Tipton, P. J. Watson, P. J. Webber, and C. W. Slinger, “100-megapixel computer-generated holographic images from active tiling—a dynamic and scalable electro-optic modulator system,” Proc. SPIE 5005, 247 (2003).
[CrossRef]

Cui, D.

W. Wu, F. Blaicher, J. Yang, T. Seder, and D. Cui, “A prototype of landmark-based car navigation using a full-windshield head-up display system,” in Proceedings of Workshop on Ambient Media Computing, ACM, 2009, pp. 21–28.

Dance, D. R.

S. Webb, D. R. Dance, and S. Evans, “The physics of image visualization in medicine,” in The Physics of Medical Imaging, S. Webb, ed. (Adam Hilger, CRC Press, Bristol and Philadelphia, 1988; Mir, Moscow, 1991).

de Beeck, M. O.

A. Redert, M. O. de Beeck, C. Fehn, W. Ijsselsteijn, M. Pollefeys, L. Van Gool, E. Ofek, I. Sexton, and P. Surman, “Advanced three-dimensional television systems technologies,” in Proceedings of First International Symposium on 3D Data Processing, Visualization and Transmission, 2002, pp. 313–319.

De Nikola, S.

S. A. Balti?ski?, I. P. Gurov, S. De Nikola, D. Koppola, and P. Ferraro, “Modern methods of digital holography,” in Problems of Coherent and Digital Optics, I. P. Gurov and S. A. Kozlov, eds. (SPb GU ITMO, St. Petersburg, 2004), pp. 91–117.

Evans, S.

S. Webb, D. R. Dance, and S. Evans, “The physics of image visualization in medicine,” in The Physics of Medical Imaging, S. Webb, ed. (Adam Hilger, CRC Press, Bristol and Philadelphia, 1988; Mir, Moscow, 1991).

Fantin, A. V.

A. V. Fantin, A. Albertazzia, and T. L. Pintoa, “An efficient mesh-oriented algorithm for 3D measurement in multiple-camera fringe projection,” Proc. SPIE 6616, 66161 (2007).
[CrossRef]

Farris, M. C.

Y. Bai, J. Bajaj, J. W. Beletic, M. C. Farris, A. Joshi, S. Lauxtermann, A. Petersen, and G. Williams, “Teledyne imaging sensors: silicon CMOS imaging technologies for X-ray, UV, visible and near infrared,” Proc. SPIE 7021, 702102 (2008).
[CrossRef]

Fehn, C.

A. Redert, M. O. de Beeck, C. Fehn, W. Ijsselsteijn, M. Pollefeys, L. Van Gool, E. Ofek, I. Sexton, and P. Surman, “Advanced three-dimensional television systems technologies,” in Proceedings of First International Symposium on 3D Data Processing, Visualization and Transmission, 2002, pp. 313–319.

Fenton, R. G.

M. Mackay, R. G. Fenton, and B. Benhabib, “Time-varying-geometry object surveillance using a multi-camera active-vision system,” Int. J. Smart Sens. Intell. Syst. 1, 679 (2008).

Ferraro, P.

S. A. Balti?ski?, I. P. Gurov, S. De Nikola, D. Koppola, and P. Ferraro, “Modern methods of digital holography,” in Problems of Coherent and Digital Optics, I. P. Gurov and S. A. Kozlov, eds. (SPb GU ITMO, St. Petersburg, 2004), pp. 91–117.

Fox, M. J.

J. Gruninger, R. L. Sundberg, M. J. Fox, R. Levine, W. F. Mundkowsky, M. S. Salisbury, and A. H. Ratcliff, “Automated optimal channel selection for spectral imaging sensors,” Proc. SPIE 4381, 43811 (2001).

Frauel, Y.

Y. Frauel, T. J. Naughton, O. Matoba, E. Tajahuerce, and B. Javidi, “Three-dimensional imaging and processing using computational holographic imaging,” Proc. IEEE 94, 636 (2006).
[CrossRef]

Fujikao, T.

S. Suyama, Y. Ishigure, H. Takada, K. Nakazawa, J. Hosohata, Y. Takao, and T. Fujikao, “Apparent 3-D image perceived from luminance-modulated two 2-D images displayed at different depths,” Vision Res. 44, 785 (2004).
[CrossRef]

Goodman, D.

D. Goodman, Statistical Optics (Wiley, New York, 1985; Mir, Moscow, 1988).

Gorthi, S. S.

S. S. Gorthi and P. Rastogi, “Fringe projection techniques: whither we are?” Opt. Lasers Eng. 48, 133 (2010).
[CrossRef]

Gruninger, J.

J. Gruninger, R. L. Sundberg, M. J. Fox, R. Levine, W. F. Mundkowsky, M. S. Salisbury, and A. H. Ratcliff, “Automated optimal channel selection for spectral imaging sensors,” Proc. SPIE 4381, 43811 (2001).

Gurov, I. P.

V. N. Vasil’ev, I. P. Gurov, and A. S. Potapov, “Mathematical methods and algorithmic assurance of the analysis and recognition of images in information–telecommunication systems,” Federal portal on scientific and innovation activity. Access regime http://www.sci-innov.ru/articles/itcs/contest_its/?entry_id=62325.

S. A. Balti?ski?, I. P. Gurov, S. De Nikola, D. Koppola, and P. Ferraro, “Modern methods of digital holography,” in Problems of Coherent and Digital Optics, I. P. Gurov and S. A. Kozlov, eds. (SPb GU ITMO, St. Petersburg, 2004), pp. 91–117.

Hahn, J.

Häusler, G.

Hong, J.

Horry, Y.

R. Otsuka, T. Hoshino, and Y. Horry, “Transpost: 360-viewable three- dimensional display system,” Proc. IEEE 94, 629 (2006).
[CrossRef]

Hoshino, H.

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R. Otsuka, T. Hoshino, and Y. Horry, “Transpost: 360-viewable three- dimensional display system,” Proc. IEEE 94, 629 (2006).
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