Figure 12.1 Central projections of retinal ganglion cells

Slides:

Advertisements

Similar presentations

Perception Chapter 4 Visual Process beyond the Retina

Advertisements

Chapter 4: The Visual Cortex and Beyond

The Primary Visual Cortex

Midterm 1 Oct. 21 in class. Read this article by Wednesday next week!

The Visual System: Feature Detection Model Lesson 17.

Central Visual Processes. Anthony J Greene2 Central Visual Pathways I.Primary Visual Cortex Receptive Field Columns Hypercolumns II.Spatial Frequency.

The Central Visual System

2002/02/05PSYC , Term 2, Copyright Jason Harrison, Visual pathways from here to there to everywhere.

Ascending Visual Pathway

Visual Fields KW Fovea on Cortex KW 8-22 Occipital Lobes are Independent KW 8-24.

Binocular Disparity points (C) nearer than fixation (P) have crossed disparity points (F) farther than fixation have uncrossed disparity.

Higher Processing of Visual Information: Lecture III

2002/01/21PSCY , Term 2, Copyright Jason Harrison, The Brain from retina to extrastriate cortex.

Question Examples If you were a neurosurgeon and you needed to take out part of the cortex of a patient, which technique would you use to identify the.

Read this article for Friday Oct 21! Trends in Neuroscience (2000) 23, Hint #1: there are at least 3 ways of getting this article Hint #2: none.

What is Stereopsis? The process in visual perception that leads to the sensation of depth due to the slightly different perspectives that our two eyes.

Blue= rods Green = Cones Pathways from the Retina In the brain, retinal ganglion axons travel to… –the hypothalamus: control bodily rhythms.

1 Biological Neural Networks Example: The Visual System.

Read Pinker article for Thurs.. Seeing in Stereo.

Exam 1 week from today in class assortment of question types including written answers.

How does the visual system represent visual information? How does the visual system represent features of scenes? Vision is analytical - the system breaks.

Higher Processing of Visual Information: Lecture I --- April 2, 2007 by Mu-ming Poo 1.Overview of the Mammalian Visual System 2.Structure of Lateral Geniculate.

The Human Visual System Short Overview. Terms: LGN, cortex, primary visual cortex, V1.

The Visual System. Figure 6.1 A cross-sectional view of the human eye Klein/Thorne: Biological Psychology © 2007 by Worth Publishers.

Chapter 10 The Central Visual System. Introduction Neurons in the visual system –Neural processing results in perception Parallel pathway serving conscious.

Visual Pathways visual hemifields project contralaterally –exception: bilateral representation of fovea! Optic nerve splits at optic chiasm about 90 %

Color vision Different cone photo- receptors have opsin molecules which are differentially sensitive to certain wavelengths of light – these are the physical.

Binocular Disparity points nearer than horopter have crossed disparity

Human Sensing: The eye and visual processing Physiology and Function Martin Jagersand.

Chapter 10 The Central Visual System. Introduction Neurons in the visual system –Neural processing results in perception Parallel pathway serving conscious.

Higher Processing of Visual Information: Lecture II

The visual system Lecture 1: Structure of the eye

Ganglion cells project to the brain via the optic nerve information is projected to contralateral cortex! Visual Pathways.

Vision is more than what we see.. Karl Lashley American Psychologist Memory storage Migraine Headaches.

Click to Play! Neuro Quiz  Michael McKeough 2008 Identify the correct question The Visual System.

Copyright © 2007 Wolters Kluwer Health | Lippincott Williams & Wilkins Neuroscience: Exploring the Brain, 3e Chapter 10: The Central Visual System.

PSYC 330: Perception Depth Perception. The Puzzle The “Real” World and Euclidean Geometry The Retinal World and Projective Geometry Anamorphic art.

Photo, p. 476 Ranulfo Romo. Figure 23.1 Vibration Discrimination Task and Performance.

Careers for Psychology and Neuroscience Majors Oct. 19th5-7pm in SU 300 Ballroom B.

Vision. Light is electromagnetic energy. One nm = one billionth of a meter The Visible Spectrum.

Higher Processing of Visual Information Lecture I --- April 2, 2007 by Mu-ming Poo 1.Overview of the Mammalian Visual System 2.Retinotopic Maps and Cortical.

Physiology of Vision: a swift overview Pixels to Percepts A. Efros, CMU, Spring 2011 Some figures from Steve Palmer.

1 Computational Vision CSCI 363, Fall 2012 Lecture 3 Neurons Central Visual Pathways See Reading Assignment on "Assignments page"

THE VISUAL SYSTEM: EYE TO CORTEX Outline 1. The Eyes a. Structure b. Accommodation c. Binocular Disparity 2. The Retina a. Structure b. Completion c. Cone.

The Visual Cortex: Anatomy

Slide 1 Neuroscience: Exploring the Brain, 3rd Ed, Bear, Connors, and Paradiso Copyright © 2007 Lippincott Williams & Wilkins Bear: Neuroscience: Exploring.

Occipital Lobe Videos: –Brain modules 8,9,10, 11 –Consciousness- Blindsight.

VISUAL SYSTEM Key points

THE VISUAL SYSTEM. LIGHT Electromagnetic radiation that travels as a wave Amplitude = brightness Wavelength = color Varies in purity (richness of colors)

Figure 2.7. Number of neural impulses in selected single cells of the monkey brain when shown differing pictures. These neurons fire the most when a face.

VS131 Visual Neuroscience Lateral Geniculate Nucleus (LGN)

Higher Visual Areas 1.Anatomy of higher visual areas 2.Two processing pathways - “ Where ” pathway for motion and depth - “ What ” pathway for form and.

The Eye: III. Central Neurophysiology of Vision L12

Innervation of the Eye and Orbit Part 1: The Optic Nerve and

Midterm 1 Oct. 6 in class Review Session after class on Monday.

How do we see in 3 dimensions?

Vision is hard Humans - vision is easy - chess is hard Computers

Outline Of Today’s Discussion 1.LGN Projections & Color Opponency 2.Primary Visual Cortex: Structure 3.Primary Visual Cortex: Individual Cells.

Binocular Disparity points nearer than horopter have crossed disparity points farther than horopter have uncrossed disparity.

1 Computational Vision CSCI 363, Fall 2012 Lecture 12 Review for Exam 1.

1 Perception and VR MONT 104S, Spring 2008 Lecture 3 Central Visual Pathways.

Central visual pathways

Anatomy of the Human Eye

Early Processing in Biological Vision

Visual Cortex Vision Science Lectures in Ophthalmology Curtis Baker.

Optic Nerve Projections

Stereopsis: How the brain sees depth

Ascending Visual Pathways

Visual System (CN II) Made by : DANI MAMO.

Central visual processing

Presentation transcript:

Figure 12.1 Central projections of retinal ganglion cells neuro4e-fig-12-01-0.jpg

Figure 12.2 The circuitry responsible for the pupillary light reflex neuro4e-fig-12-02-0.jpg

Figure 12.2 The circuitry responsible for the pupillary light reflex (Part 1) neuro4e-fig-12-02-1r.jpg

Figure 12.2 The circuitry responsible for the pupillary light reflex (Part 2) neuro4e-fig-12-02-2r.jpg

Figure 12.3 Projection of the visual fields onto the left and right retinas neuro4e-fig-12-03-0.jpg

Figure 12.3 Projection of the visual fields onto the left and right retinas (Part 1) neuro4e-fig-12-03-1r.jpg

Figure 12.3 Projection of the visual fields onto the left and right retinas (Part 2) neuro4e-fig-12-03-2r.jpg

Figure 12.3 Projection of the visual fields onto the left and right retinas (Part 3) neuro4e-fig-12-03-3r.jpg

Figure 12.4 Binocular field of view onto two retinas and relation to crossing of fibers in optic chiasm neuro4e-fig-12-04-0.jpg

Figure 12.5 Visuotopic organization of the striate cortex in the right occipital lobe neuro4e-fig-12-05-0.jpg

Figure 12.5 Visuotopic organization of the striate cortex in the right occipital lobe (Part 1) neuro4e-fig-12-05-1r.jpg

Figure 12.5 Visuotopic organization of the striate cortex in the right occipital lobe (Part 2) neuro4e-fig-12-05-2r.jpg

Figure 12.6 Consequences of damage at different points along the primary visual pathway neuro4e-fig-12-06-0.jpg

Figure 12.7 Course of the optic radiation to the striate cortex neuro4e-fig-12-07-0.jpg

Figure 12.8 Neurons in the primary visual cortex respond selectively to oriented edges neuro4e-fig-12-08-0.jpg

Figure 12.8 Neurons in the primary visual cortex respond selectively to oriented edges (Part 1) neuro4e-fig-12-08-1r.jpg

Figure 12.8 Neurons in the primary visual cortex respond selectively to oriented edges (Part 2) neuro4e-fig-12-08-2r.jpg

Figure 12.9 Representation of visual image by neurons selective for different stimulus orientations neuro4e-fig-12-09-0.jpg

Figure 12.10 Organization of primary visual (striate) cortex neuro4e-fig-12-10-0.jpg

Figure 12.10 Organization of primary visual (striate) cortex (Part 1) neuro4e-fig-12-10-1r.jpg

Figure 12.10 Organization of primary visual (striate) cortex (Part 2) neuro4e-fig-12-10-2r.jpg

Figure 12.11 The basis of functional maps in primary visual cortex neuro4e-fig-12-11-0.jpg

Figure 12.11 The basis of functional maps in primary visual cortex (Part 1) neuro4e-fig-12-11-1r.jpg

Figure 12.11 The basis of functional maps in primary visual cortex (Part 2) neuro4e-fig-12-11-2r.jpg

Figure 12.12 Functional imaging techniques reveal the orderly mapping of orientation preference in primary visual cortex neuro4e-fig-12-12-0.jpg

Figure 12.13 Mixing of the pathways from the two eyes first occurs in the striate cortex neuro4e-fig-12-13-0.jpg

Figure 12.13 Mixing of the pathways from the two eyes first occurs in the striate cortex (Part 1) neuro4e-fig-12-13-1r.jpg

Figure 12.13 Mixing of the pathways from the two eyes first occurs in the striate cortex (Part 2) neuro4e-fig-12-13-2r.jpg

Figure 12.14 Binocular disparities are generally thought to be the basis of stereopsis neuro4e-fig-12-14-0.jpg

Box 12A(1) Random Dot Stereograms and Related Amusements neuro4e-box-12-a(1)-0.jpg

Box 12A(1) Random Dot Stereograms and Related Amusements (Part 1) neuro4e-box-12-a(1)-1r.jpg

Box 12A(1) Random Dot Stereograms and Related Amusements (Part 2) neuro4e-box-12-a(1)-2r.jpg

Box 12A(2) Random Dot Stereograms and Related Amusements neuro4e-box-12-a(2)-0.jpg

Figure 12.15 Magno-, parvo-, and koniocellular pathways neuro4e-fig-12-15-0.jpg

Figure 12.15 Magno-, parvo-, and koniocellular pathways (Part 1) neuro4e-fig-12-15-1r.jpg

Figure 12.15 Magno-, parvo-, and koniocellular pathways (Part 2) neuro4e-fig-12-15-2r.jpg

Figure 12.16 Subdivisions of the extrastriate cortex in the macaque monkey neuro4e-fig-12-16-0.jpg

Figure 12.16 Subdivisions of the extrastriate cortex in the macaque monkey (Part 1) neuro4e-fig-12-16-1r.jpg

Figure 12.16 Subdivisions of the extrastriate cortex in the macaque monkey (Part 2) neuro4e-fig-12-16-2r.jpg

Figure 12.17 Localization of multiple visual areas in the human brain using fMRI neuro4e-fig-12-17-0.jpg

Figure 12.17 Localization of multiple visual areas in the human brain using fMRI (Part 1) neuro4e-fig-12-17-1r.jpg

Figure 12.17 Localization of multiple visual areas in the human brain using fMRI (Part 2) neuro4e-fig-12-17-2r.jpg

Figure 12.18 The visual areas beyond the striate cortex are broadly organized into two pathways neuro4e-fig-12-18-0.jpg