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Office: Gamow Tower, F-521 Email: ivan.smalyukh@colorado.edu Phone: 303-492-7277 Lectures: Tuesdays & Thursdays, 3:30 PM - 4:45 PM Office hours: Mondays & Fridays, 3:30 PM – 4:30 PM TA: Jhih-An Yang jhihan.yang@colorado.edu.
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Office: Gamow Tower, F-521 • Email: • ivan.smalyukh@colorado.edu • Phone: 303-492-7277 • Lectures: • Tuesdays & Thursdays, • 3:30 PM - 4:45 PM • Office hours: • Mondays & Fridays, • 3:30 PM – 4:30 PM • TA: Jhih-An Yang • jhihan.yang@colorado.edu Physics 1230: LightandColorIvan I. Smalyukh, Instructor Class # 18
The remaining lectures: • Ch. 7 (Retina and visual perception), • Ch. 9 & 10 (color & color perception). We are here
Ch. 7 – Visual Perception We are here • Parts of the visual processing system • Lightness and brightness • Retinal processing: Lateral inhibition • Hermann grid • Receptive field • Motion illusion • Craik O’Brien illusion & simultaneous lightness contrast • Other optical illusions
The Retina: Detecting the light and processing the images The retina and optic nerves are recognized as actually parts of the brain (like your olifactory bulb in the nose). They start development IN the brain and migrate… Has 108 nerve endings to detect image rods, for high sensitivity (night vision) cones, for color and detail, 7 million optic nerve = 106 transmission lines fovea, region of best vision (cones) More nerves in your retina than some creatures have in their entire brains. Processing Power.
Rods and cones • Rhodopsin, a photochemical, responds to lightIt is destroyed and reformed.Signal goes to a synapse, a gap between nerve cells • There are 3 kinds of cones for 3 colors red, green, blue (more later). A great deal is understood about how the individual cells of the retina receive light, respond to light, and transmit signals.
Rods and cones Example: Rhodopsin and photosensitivity Light drives a change in molecular shape. Opens/closes membrane Photo-responsive membrane protein is known in atomic detail We will skip Most of cellular detail BECAUSE…
Does our understanding of the individual rods, cones, and other cells of the retina do much to explain this?: (A) Creitanly (B) Myaby Not Mcuh We need to understand how NETWORKS of cells WORK TOGETHER to let us perceive.
Layers of the retina Light
See text fig. 7.2 Layers of the retina are CROSS Connected From the following article: Neurobiology: Bright blue times Russell G. Foster Nature 433, 698-699(17 February 2005) doi:10.1038/433698a a, The rods (R) and cones (C) convey visual information to the ganglion cells (G) through the bipolar cells (B). Horizontal cells (H) allow lateral connections between rods and cones. Amacrine cells (A) allow lateral connections between bipolar and ganglion cells. The optic nerve is formed from the axons of all the ganglion cells. A subset of ganglion cells (MG cells) also detects light directly; for this, they require the photopigment melanopsin, as now confirmed1, 2, 3. b, Light, via melanopsin, causes changes in Ca2+ levels in MG cells9 (a fluorescent Ca2+ indicator was used here). Counterintuitively, light passes through the transparent ganglion layer to reach the rods and cones.
Connections and cross connections are MOST important. Photoreceptors: rods and cones connected to the bipolar cells connected to the ganglion cells, funnel “data” through axons into the optic nerve sideways connectors (these help with analysis) horizontal cells, next to the photoreceptors amacrine cells
Clicker question The arrow points to: • Photoreceptors • Horizontal cells • Bipolar cells • Amacrine cells • Ganglion cells
Clicker question The arrow points to: • Photoreceptors • Horizontal cells • Bipolar cells • Amacrine cells • Ganglion cells
Optic chiasma and brain structure Brain damage on the left side hurts vision on the right side. See text fig. 7.3
Brain anatomy Optic chiasma Left field of view goes to right brain Right field of view goes to left brain from both eyes Visual cortex is where you “see” Brain damage at this location hurts vision.
Clicker question If the left side of your brain is injured, you might lose vision in your • left eye • right eye • left field of view • right field of view • some loss in left and right field of view
All this ‘hardware’ allows us to perceive the world and function in it. Many complicated sub-systems have developed. Let’s study a few to get some insight into how vision works.
Interesting collective behavior 1: We detect RELATIVE Lightness, not total Brightness Brightness: amount of light Lightness: property of a surface newspaper = 0.65 (reflectance) printer paper = 0.84 photo quality paper = 0.90-0.99 Total amount of light is far less important than the relative amount of light, particularly as compared with nearby objects. Demo with room lights.
Lightness and brightness Lightness constancy: brain and eye correct for amount of light so that white, gray, and black look the same independent of brightness. Weber’s law: we think lightness is equally spaced when the ratios are equally spaced Example: lightness 0.5, 0.25, 0.125 look equally spaced.These numbers are ½, ¼, 1/8 etc. The spacing that looks equal is not 0.9, 0.8, 0.7, etc. Demo: Lights on or lights off
Retinal processing that allows Relative Lightness sensitivity: Amacrine and horizontal cells “turn down” the signals from areas adjacent to bright areas. “Lateral Inhibition” See text fig. 7.5
“Receptive field” Nerve cell fires rapidly The rods/cones and local cells are connected in a group: Nerve cell doesn’t fire Center of group causes nerves to fire if illuminated. Surrounding group causes nerves to STOP firing if they are illuminated. Nerve cell doesn’t fire Nerve cell fires only a bit See text fig. 7.12