Normal and Defective Colour Vision
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A termék adatai:
- Kiadó OUP Oxford
- Megjelenés dátuma 2003. május 8.
- ISBN 9780198525301
- Kötéstípus Keménykötés
- Terjedelem460 oldal
- Méret 248x174x30 mm
- Súly 950 g
- Nyelv angol
- Illusztrációk 4pp colour plates, numerous tables and figures 0
Kategóriák
Rövid leírás:
A landmark publication in vision research - this is the definitive work on colour vision, edited by leading vision scientists - John Mollon, Joel Pokorny, and Ken Knoblauch. Together they have brought together a stellar list of contributors, spanning the disciplines with an interest in this area. The book presents a state of the art review of this interdisciplinary topic, aimed at all researchers in the vision sciences.
TöbbHosszú leírás:
The topic of colour vision is one that integrates research from psychology, neuroscience, biology, opthalmology, physics, and genetics. How do we make sense of colour in the world, and how has such an ability evolved in humans? How are colours discriminated by the retina, and how does the brain interpret chromatic information? How can our genes influence the way in which we perceive colours? Why do some people have problems perceiving colours, and what occupational difficulties may they face? In what ways is colour vision altered by disease or toxins?
John Mollon, Joel Pokorny, and Ken Knoblauch are leading authorities on the perception of colour. Together they have brought together a distinguished list of contributors to provide an interdisciplinary review of the field. An historical introduction marks the bicentennial of Thomas Young's trichromatic theory and provides useful background for the newcomer to the topic of colour vision. Carefully edited and indexed, this book is aimed at students and researchers in the visual sciences, in perceptual psychology, and in sensory neuroscience. It will be a definitive text on colour perception for some years to come.
Normal and Defective Colour Vision . . . succeeds both in strengthening our understanding of existing findings and in identifying gaps in our knowledge of chromatic processes that can be addressed in future studies. In this respect, the book as a whole is significantly more valuable than the sum of its constituent parts and is therefore a 'must' for both students and researchers in this field.
Tartalomjegyzék:
Thomas Young and the Trichromatic Theory of Colour Vision
Section I: Photoreceptors and their evolution
Electrons and x-rays reveal the structure of rhodopsin: A prototypical G protein-coupled receptor - Implications for colour vision
Photopigment polymorphism in prosimians and the origins of primate trichromacy
Did primate trichromacy evolve for frugivory or folivory?
Lack of S-opsin expression in the brush tailed porcupine (Atherurus africanus) and other mammals. Is the evolutionary persistence of S-cones a paradox?
The arrangement of L and M cones in human and a primate retina
Comparison of human and monkey pigment gene promoters to evaluate DNA sequences proposed to govern L:M cone ratio
Section II: Retinal Processes
Structure of receptive field centers of midget retinal ganglion cells
The neural circuit providing input to midget ganglion cells
Coding of position of achromatic and chromatic edges by retinal ganglion cells
Section III: Spatial and Temporal Aspects of Colour Perception
Psychophysical correlates of parvo- and magnocellular function
Spatial contrast sensitivity for pulsed and steady pedestal stimuli
Chromatic assimilation: evidence for a neural mechanism
Reaction times to stimuli in isoluminant colour space
Integration times reveal mechanisms responding to isoluminant chromatic gratings: a two-centre visual evoked potential study
Temporal frequency and contrast adaptation
Contribution of achromatic and chromatic contrast signals to Fechner-Benham subjective colours
Sensitivity to movement of configurations of achromatic and chromatic points in amblyopic patients
Convergence as a function of chromatic contrast: a possible contributor to depth perception
Secton IV: Rods and Colour Vision
The influence of rods on colour naming during dark adaptation
Stimulus duration affects rod influence on hue perception
Section V: Natural Scenes and Colour Constancy
The Verriest Lecture: Colour discrimination, colour constancy and natural scene statistics
Tritanopic colour constancy under daylight changes?
Red-green colour deficiency and colour constancy under orthogonal-daylight changes
Calculating appearances in complex and simple images
The effect of global contrast distribution on colour appearance
Section VI: Colour Spaces and their Variation
Schopenhauer's 'parts of daylight' in the light of modern colorimetry
Representing an observer's matches in an alien colour space
Macular pigment: Nature's notch filter
How to find a tritan line
Some properties of the physiological colour system
Section VII: Inherited Colour Deficiency: Molecular Genetics
Genotypic variation in multi-gene dichromats
Hybrid pigment genes, dichromacy and anomalous trichromacy
Middle wavelength sensitive photopigment gene expression is absent in deuteranomalous colour vision
Section VIII: Inherited Colour Deficiency: Psychophysics and Tests
Preliminary norms for the Cambridge Colour Test
Evaluation of 'Colour vision testing made easy'
Survey of the colour vision demands in fire-fighting
Lantern colour vision tests: one light or two
Extreme anomalous trichromatism
Colour naming, colour categories and central colour-coding in a case of X-linked incomplete achromatopsia
Section IX: Acquired Deficiencies of Colour Vision
Effects of retinal detachment on S and M cone function in an animal model
Colour vision in central serous chorioretinopathy
Early vision loss in diabetic patients assessed by the Cambridge Colour Test
Colour-vision disturbances in patients with arterial hypertension
Visual dysfunction following mercury exposure by breathing mercury vapour or by eating mercury-contaminated food
