The Human Eye: an intelligent optical sensor

1.      N. Lauinger Beugungsgitter auf Grenzflächen des optischen Systems des menschlichen Auges, Acta Ophthalmologica Suppl.136, Kopenhagen (1978)

2.      N. Lauinger 3D grating optics of Human Vision, Acta Ophthalmologica Suppl.199, Kopenhagen (1991)

3.      N. Lauinger 3D grating optical retinal chip and stimulus-adaptive robotic vision, SPIE Proceedings Vol.1825 Intelligent Robots and Computer Vision XI, 78-103, (1992)

4.      N. Lauinger A new interpretation of the Stiles-Crawford effects in human vision, Journal of Biological Physics 19: 167-188 (1994)

5.      N. Lauinger The two axes of the human eye and inversion of the retinal layers: the basis for the interpretation of the retina as a phase grating optical cellular 3D chip, SPIE Proceedings Vol.2353 Intelligent Robots and Computer Vision XIII (1994) 549

6.      N. Lauinger Brightness, hue and saturation in photopic vision: a diffraction-optical result of illuminant intensity and wavelength in the cellular phase grating 3D chip of the inverted human retina, SPIE Proceedings Vol. 2353 Intelligent Robots and Computer Vision XIII (1994), 567-577

7.      N. Lauinger The two axes of the Human Eye and Inversion of the retinal layers: the basis for the interpretation of the retina as a phase grating optical cellular 3D chip, Journal of Biological Physics 19 (1994), 243-257

8.      Carbon, M.A. (Institut für Optosensorik Dr. N. Lauinger) Using diffraction theory of human vision for design of color vision devices, SPIE Proceedings Vol. 2353 Intelligent Robots and Computer Vision XIII (1994), 550-560

9.      N. Lauinger The relationship between brightness, hue and saturation when the inverted human retina is interpreted as a cellular diffractive 3D chip, SPIE Proceedings Vol.2588 Intelligent Robots and Computer Vision XIV (1995), 208-232

10.  N. Lauinger The Inverted Retina of the Human Eye: a tri-chromatic 4D Space-time Optical Correlator, SPIE Proceedings Vol.2904 Intelligent Robots and Computer Vision XV (1996), 344-360

11.  N. Lauinger, M. Pinnow, E. Görnitz, Phase grating from ordered polymer lattices for optical image pre-processing, Journal of Biological Physics, Vol.23 No.2 (1997), 73-88

12.  N. Lauinger The two axes of the human eye and inversion of the retinal layers: the basis for interpretation of the retina as a phase grating optical cellular 3D chip, John Dalton’s Colour Vision Legacy, Taylor & Francis, London (1997), 623-630

13.  N. Lauinger Brightness, hue and saturation in photopic vision: a diffraction-optical result of illuminant intensity and wavelength in the cellular phase grating 3D chip of the inverted human retina, John Dalton’s Colour Vision Legacy, Taylor & Francis, London (1997), 631-638

14.  N. Lauinger Transformation of light double cones in the human retina: the origin of trichromatism, of 4D-spatiotemporal vision and of patchwise 2D Fourier transformation in Talbot imaging, SPIE Proceedings Vol.3208 Intelligent Robots and Computer Vision XVI (1997), 302-327

15.  N. Lauinger Training or inheritance in human vision: a critical test for understanding and engineering of intelligent optical systems, SPIE Proceedings Vol.3208 Intelligent Robots and Computer Vision XVI (1997), 49-55

16.  S. Kusch, J. Schwab, N. Lauinger Optical filter performing localized image transformations using volume holograms, SPIE Proceedings Vol.3208 Intelligent Robots and Computer Vision XVI (1997), 437-444

17.  R. Schaefer, J. Schwab, N. Lauinger New developments in optical grating technology for machine vision and industrial sensors, SPIE Proceedings Vol.3208 Intelligent Robots and Computer Vision XVI (1997), 428-436

18.  M. Carbon, N. Lauinger, J. Schwab Self-imaging of 3D phase gratings, European Optical Society Part A: Pure and Applied Optics (1998)

19.  M. Seib, R. Schaefer, N. Lauinger A Passive Multi-Channel 3D Range Sensor Using the Pupil Division and Temporal Phase Measurement Method, OPTO Proceedings Erfurt (1998), 9.2, 221-226

20.  M. Seib, R. Schaefer, N. Lauinger Ein passiv arbeitender Multi-Abstandssensor nach dem Prinzip der Pupillenteilung und temporärer Phasenmessung, TM Technisches Messen 65 (7-8/1998), 260-263

21.  N. Lauinger Grating-optical diffractive image pre-processing in optical sensors copying human vision (OPTORETINA), SPIE Proceedings Vol.3522 Intelligent Robots and Computer Vision XVII (1998), 328-342

22.  M. Carbon Diffraction of light by 3D hexagonal phase gratings: applications for robotic color vision. SPIE Proceedings Vol.3522 Intelligent Robots and Computer Vision XVII (1998), 399-411

23.  N. Lauinger Diffractive centro-symmetric 3D-transmission phase gratings, positioned at the image plane of optical systems, transform light-like 4D-world as tunable resonators into spectral metrics, SPIE Proceedings Vol.3837 Intelligent Robots and Computer Vision XVIII, 154-163 (1999).

24.  N. Lauinger Grating-optical image pre-processing leads Opto-Electronics into Opto²-, Opto³- and Opto-expn-Electronics, SPIE Proceedings Vol.3837 (1999), 40-44

25.  N. Lauinger, B. Badenhop Diffractive 3D grating-optical sensor with tri-chromatic color constancy at adaptation to variable illuminants, SPIE Proceedings Vol.4197 Intelligent Robots and Computer Vision XIX (2000), 352-357

26.   N. Lauinger Diffractive 3D phase gratings will qualify optical sensors and image processing technologies for reaching performances of human vision, SPIE Proceedings Vol.4197 Intelligent Robots and Computer Vision XIX (2000), 27-43

27.  N. Lauinger Diffractive 3D grating-optical image processing: an interference-optical Volterra filter resonator?, SPIE Proceedings Vol.4572 Intelligent Robots and Computer Vision XX, 61-69 (2001)

28.  N. Lauinger Learning from biotechnology; milestones in the prenatal engineering of an intelligent optical sensor: the human eye, SPIE Proceedings Vol.4572 Intelligent Robots and Computer Vision XX, 231-240 (2001).

29.  N. Lauinger Prenatal Development of the Human Eye: A Starting Point for Innovation in Optics? OPTO 2002 Proceedings, 7-17, Erfurt 2002.

30.  N. Lauinger Illuminant-Adaptive Diffractive-Optical RGB Colour Sensor: 3D grating-optical cross-correlator calculating Coloured Shadows in Human Vision. SPIE Proceedings Photonics East, Providence, Vol.5267, 26-42, 2003

31.  N. Lauinger Diffractive-Optical Correlators: chances to make optical image pre-processing as intelligent as human vision. SPIE Proceedings OpticsEast, Philadelphia, Vol.5608, 36-44, 2004

32.  N. Lauinger 4D-RGB diffractive-optical correlator in the human eye: the hardware for a hierarchy of spectral space-time transformations in color vision. OpticsEast Boston: Intelligent Robots and Computer Vision XXIII, 2005, SPIE-Vol.6006-31.

33.  N. Lauinger Retinex software or diffractive-optical correlator hardware: the basis of human color vision? Optics East Boston: Intelligent Robots and Computer Vision XXIII, 2005, SPIE-Vol.6006-4.

34.  N. Lauinger Coloured Shadows: Diffractive-Optical Cross-Correlations in the Human Eye. The Missing Link between Physics and Psychology, Newton and Goethe. SPIE Annual Meeting 2003 San Diego/CA, AM 100-Conference in honour of Professor Emil Wolf/Rochester. In “Tribute to Emil Wolf – Science and Engineering; Legacy of Physical Optics, SPIE Press, Bellingham, Washington 2005.

35.  N. Lauinger New experimental diffractive-optical data on E. Land’s Retinex mechanism in human color vision (Part 1) Optics East Boston: Intelligent Robots and Computer Vision XXIV, SPIE-Vol. 6384-06 (2006)

36.  J. Haus, N. Lauinger Optische Gitter: Die Abbildung der Realität. 75 Jahre berührungslose dynamische Messtechnik auf der Basis optischer Gitter. Laser-Journal Wiley-VCH Verlag 2007, 43-47.

37.  N. Lauinger What the human eye tells the brain: a new approach toward a hardware-based modeling of mental functions.Optics East Boston: Intelligent Robots and Computer Vision XXV, SPIE-Vol. 6764-5 (2007)

38.  N. Lauinger New experimental diffractive-optical data on E. Land’s Retinex mechanism in human color vision: Part II. Optics East Boston: Intelligent Robots and Computer Vision XXV, 2007 SPIE-Vol.6764-18

39.  N. Lauinger The Human Eye: an intelligent optical sensor. (The inverted human retina: a diffractive-optical correlator). International Frequency Sensor Association IFSA, Toronto, Canada. 2014

40.  N. Lauinger Prevention of Myopia: the eye ought to exercise the use of the 3rd dimension of the visible at an early stage. Annexe to N. Lauinger The Human Eye: an intelligent optical sensor. (The inverted human retina: a diffractive-optical correlator). International Frequency Sensor Association IFSA, Toronto, Canada. 2014

41.  N. Lauinger Space grating optical structure of the retina and RGB-color vision. Optical Society of America, Applied Optics Vol.56, No.4, February 1 2017 (1261-1265)

42.  N. Lauinger Lichtbeugung im Raumgitter der Netzhaut des Auges und Fresnel-Nahfeld-Interferenzen transformieren das sichtbare Spektrum in den RGB-Raum. DGaO-Proceedings 2017, ISSN: 1614-8436

43.  N. Lauinger Myopie-Prävention. Das Auge muss früh den Umgang mit der dritten Dimension des Sichtbaren trainieren. FOCUS Nr. 2014-11 November 2014 (28-30), Nr.2014-12 Dezember 2014 (26-29), Nr. 2015-02 Februar 2015 (34-37)

44.  N. Lauinger Retina: Lichtbeugung im Raumgitter. DER AUGENSPIEGEL, November 2017 (38-42), Dezember 2017 (40-43)

45.  N. Lauinger Gehirn und Auge: Entwicklung der kortikalen Informationsverarbeitung in der Netzhaut. DER AUGENSPIEGEL, April 2018 (28-33), Mai 2018 (30-34)

46.  N. Lauinger Fresnel Nearfield Space-Grating Optics in the Human Retina Explains Human Color and Dimlight Vision. In: Advances in Optics, IFSA-Publishing (S.Y.Yurish, Editor) Vol.1, 2018 (415-436)

47.  N. Lauinger Das Gehirn entwickelt vor der Geburt das Auge und in der Netzhaut das ‚Gehirn im Auge‘ für die kortikale Informationsverarbeitung. DGaO-Proceedings 2018

48.  N. Lauinger Das menschliche Sehorgan ist ein prominentes Gleichgewichtsorgan. DER AUGENSPIEGEL, Herbst 2018 in Vorb.