Presentation is loading. Please wait.

Presentation is loading. Please wait.

CS-321 Dr. Mark L. Hornick 1 Color Perception. CS-321 Dr. Mark L. Hornick 2 Color Perception.

Published byReynold Chambers Modified over 8 years ago

Similar presentations

Presentation on theme: "CS-321 Dr. Mark L. Hornick 1 Color Perception. CS-321 Dr. Mark L. Hornick 2 Color Perception."— Presentation transcript:

1 CS-321 Dr. Mark L. Hornick 1 Color Perception

2 CS-321 Dr. Mark L. Hornick 2 Color Perception

3 3 Color Spectrum RedViolet 750 THz430 THz 400 nm700 nm

4 CS-321 Dr. Mark L. Hornick 4 Additive colors

5 CS-321 Dr. Mark L. Hornick 5

6 6 The Human Eye The photosensitive part of the eye is called the retina. The retina is largely composed of two types of cells, called rods and cones. Only the cones are responsible for color perception.

7 CS-321 Dr. Mark L. Hornick 7 The Fovea

8 CS-321 Dr. Mark L. Hornick 8 There are three types of cones, referred to as S, M, and L. They are roughly equivalent to blue, green, and red sensors, respectively. Their peak sensitivities are located at approximately 430nm, 560nm, and 610nm for the "average" observer. Colorblindness results from a deficiency of one cone type. 400 nm 700 nm

9 CS-321 Dr. Mark L. Hornick 9 RGB Color matching functions

10 CS-321 Dr. Mark L. Hornick 10 Color Perception Different spectra can result in a perceptually identical color sensations called metamers Color perception results from the simultaneous stimulation of 3 cone types (trichromat) Our perception of color is also affected by surround effects and adaptation Different spectral distributions that “look” the same Infinitely many metamers produce the same perceived color

11 CS-321 Dr. Mark L. Hornick 11 Primary Colors Set of colors E.g., phosphor colors Combined to produce colors Within a specified gamut Can’t produce all visible colors Good enough approximation for most cases

12 CS-321 Dr. Mark L. Hornick 12 CIE Commission Internationale de l’Éclairage International Commission on Illumination 1931 Color primaries Imaginary colors Chromaticity diagram

13 CS-321 Dr. Mark L. Hornick 13 CIE Color Primaries Color-matching functions Mix x,y,z primaries Match any visible color

14 CS-321 Dr. Mark L. Hornick 14 CIE Chromaticity Diagram

15 CS-321 Dr. Mark L. Hornick 15 CIE Diagram Details SIGGRAPH 1995 Educator’s Slides Spectral colors around curve 700 600 580 560 540 520 510 500 490 480 “Line of purples” White reference (C)

16 CS-321 Dr. Mark L. Hornick 16 Color Gamut Line between color points indicates mixing results. Polygon (triangle) connecting primaries delimits gamut. 700 600 580 560 540 520 510 500 490 480

17 CS-321 Dr. Mark L. Hornick 17 Color Models (1) RGB: red,green,blue YIQ: luminance, chrominance Y: luminance, 4 MHz I: orange-cyan, 1.5 MHz Q: green-magenta, 0.6 MHz CMY: cyan, magenta, yellow Subtractive primaries (CMYK?)

18 CS-321 Dr. Mark L. Hornick 18 Subtractive colors

19 CS-321 Dr. Mark L. Hornick 19 Color Models (2) HSV: hue, saturation, value Hue: “color” Saturation: purity of color Value: black to white HLS: hue, lightness, saturation

Download ppt "CS-321 Dr. Mark L. Hornick 1 Color Perception. CS-321 Dr. Mark L. Hornick 2 Color Perception."

Similar presentations

4.1 Si23_03 SI23 Introduction to Computer Graphics Lecture 4 – Colour Models.

4.1 Si23_03 SI23 Introduction to Computer Graphics Lecture 4 – Colour Models.
CS 445 / 645 Introduction to Computer Graphics Lecture 13 Color Color.

CS 445 / 645 Introduction to Computer Graphics Lecture 13 Color Color.
Introduction to Computer Graphics ColorColor. Specifying Color Color perception usually involves three quantities: Hue: Distinguishes between colors like.

Introduction to Computer Graphics ColorColor. Specifying Color Color perception usually involves three quantities: Hue: Distinguishes between colors like.
Color To understand how to make realistic images, we need a basic understanding of the physics and physiology of vision.

Color To understand how to make realistic images, we need a basic understanding of the physics and physiology of vision.
Color Image Processing

Color Image Processing
Light Light is fundamental for color vision Unless there is a source of light, there is nothing to see! What do we see? We do not see objects, but the.

Light Light is fundamental for color vision Unless there is a source of light, there is nothing to see! What do we see? We do not see objects, but the.
School of Computing Science Simon Fraser University

School of Computing Science Simon Fraser University
CS 4731: Computer Graphics Lecture 24: Color Science

CS 4731: Computer Graphics Lecture 24: Color Science
SWE 423: Multimedia Systems Chapter 4: Graphics and Images (2)

SWE 423: Multimedia Systems Chapter 4: Graphics and Images (2)
© 2002 by Yu Hen Hu 1 ECE533 Digital Image Processing Color Imaging.

© 2002 by Yu Hen Hu 1 ECE533 Digital Image Processing Color Imaging.
Color.

Color.
What is color for?.

What is color for?.
Color Representation Lecture 3 CIEXYZ Color Space CIE Chromaticity Space HSL,HSV,LUV,CIELab X Z Y.

Color Representation Lecture 3 CIEXYZ Color Space CIE Chromaticity Space HSL,HSV,LUV,CIELab X Z Y.
COLOR and the human response to light

COLOR and the human response to light
Basic Color Theory Susan Farnand

Basic Color Theory Susan Farnand
1 CSCE441: Computer Graphics: Color Models Jinxiang Chai.

1 CSCE441: Computer Graphics: Color Models Jinxiang Chai.
Color Models 10 2 4 6 8 12 10 14 10 20 10 16 10 18 AM Radio FM Radio + TV Microwave Infrared Ultraviolet Visible.

Color Models AM Radio FM Radio + TV Microwave Infrared Ultraviolet Visible.
Human Vision CS200 Art Technology Spring 2011. The Retina Contains two types of photoreceptors – Rods – Cones.

Human Vision CS200 Art Technology Spring The Retina Contains two types of photoreceptors – Rods – Cones.
CS 376 Introduction to Computer Graphics 01 / 26 / 2007 Instructor: Michael Eckmann.

CS 376 Introduction to Computer Graphics 01 / 26 / 2007 Instructor: Michael Eckmann.
Color Models and Color Applications

Color Models and Color Applications

Similar presentations

Ads by Google