Vision: Subjective and Objective Issues Oleh Tretiak Medical Imaging Systems 2002
Why Study Vision Understand how to display images Understand what is seen Understand how vision works
Sources of Information Physics of vision Neurophysiology of vision Psychology of vision Psychophysics
References David Hubel, Eye, Brain, and Vision, Henry Hold & Company, 1995 James P. C. Southall, Physiological Optics, Dover, 1961 Vicki Bruce, Patrick R. Green, Mark A. Georgeson, Visual Perception: Physiology, Psychology, and Ecology, Psychology Press, 1996
Visual Pathway - Anatomy
Visual Pathway - Symbolic
The Retina and the Eye
The Eyeball
Vision and Eye Fixation (motion)
Half-retina maps
Layers of the Geniculate Nucleus
Section through Striate Cortex
Map From Retina to Striate Cortex
Striate Cortex Input/Output
Index of refraction Cornea (n 2 )1.376 Aqueous humor and vitreous body (n 3 = n 7 ) Outer portion of lens (n 4 = n 6 )1.386 Core-lens (n 5 )1.406 The model is due to Gullstrand (1924). The power of the eye in this model ranges from dptr (diopters) to dptr. Most of the refraction (43 dptr) is due to the cornea.
Subjective Intensity (Contrast) Models In a model for subjective intensity, let x by the brightness (power/area) and y the subjective brightness (contrast). Both x and y range from 0 to 100. Logarithmic model: Power law model: On the next slide we show thirty four steps designed to produce uniform contrast with (1) linear, power law with gamma = 1, (2) power law, gamma = 0.7, and (3) logarithmic. Note that the appearance of this depends on the transfer function of the display.
Simultaneous Contrast Examples Background = 245, circles = 210, 225, and 235 Background = 70, circle = 60
The circles have the same objective intensity.
‘Typical’ Visual Spatial Response
Objective value (intensity) Subjective (perceived) value Mach Bands
‘Typical’ visual temporal response
Boundaries Brightness Texture
Shape Perception
Size Perception