Visual Sensation & Perception How do we see?. Structure of the eye.

Slides:

Advertisements

Similar presentations

Perception Chapter 4 Visual Process beyond the Retina

Advertisements

Chapter 4: The Visual Cortex and Beyond

What do we know about Primary Visual Cortex (V1)

Chapter 6 Vision. Sensation and Perception: Important Vocabulary Terms Sensation is the process of receiving, transducing, and coding stimulus energy.

The Central Visual System

Vision: Stimulus and physiology. Light / electromagnetic radiation ● What is light? One kind of electromagnetic radiation (emr includes lots of other.

Ascending Visual Pathway

Parts of the Eye - Pupil.

Exam in 12 days in class assortment of question types including written answers.

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.

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

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

Visual Processing Structure of the Retina Lateral Inhibition Receptive Fields.

Visual System: Overview of Visual Pathway.

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 Human Eye and Vision 2 (Processing The Image)

Visual Sensation & Perception How do we see?. Structure of the eye.

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

VISUAL PATHWAYS Organization of LGN of thalamus Organization of Visual Cortex What Stream How Stream The Binding Problem.

The Eye. A Model for Sensing  Three components: Stimulus detection – a specialized sensory neuron Reception – where neurons receive information from.

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

Ch 31 Sensation & Perception Ch. 3: Vision © Takashi Yamauchi (Dept. of Psychology, Texas A&M University) Main topics –convergence –Inhibition, lateral.

The visual system Lecture 1: Structure of the eye

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

Retina  takes the information from its 100 million photoreceptors about 1 million optic nerve axons.  Interposed between the photoreceptor.

University Studies 15A: Consciousness I The Neurobiology of Vision.

Vision Biology/Psychology Some introductory thoughts Sensory world in general is basically a representation of the real world So, we have a rich.

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"

Psychology 4051 The Retina and LGN. Retino-Geniculate-Cortical Pathway.

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

Sensation Vision The Eye Theories Hearing The Ear Theories Other Senses Smell Taste Pain Gestalt Principles Perceptual Constancies Perception Basic Principles.

Vision Structure of the Eye We only use light energy to see.

Physiology of Vision (2)

Vision Psychology Some introductory thoughts Sensory world in general is basically a representation of the real world Sensory world in general is.

Sensation and Perception Sensation: your window to the world Perception: interpreting what comes in your window.

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

Chapter 3: Neural Processing and Perception. Neural Processing and Perception Neural processing is the interaction of signals in many neurons.

1 Computational Vision CSCI 363, Fall 2012 Lecture 5 The Retina.

The Eye. Energy v. Chemical senses Energy SensesChemical Senses.

Vision Photoreceptor cells Rod & Cone cells Bipolar Cells Connect in between Ganglion Cells Go to the brain.

Dr. Raj Patel OD - Vancouver Vision Clinic

The Eye: III. Central Neurophysiology of Vision L12

Sensation and Perception Module 18 Vision. Energy=Light We only see a small spectrum of light rays 2 characteristics determine our sensory experiences.

Keith Clements Introduction to Neuroscience

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

Sensory Neural Systems 5 February 2008 Rachel L. León

Sensation and Perception. Transformation of stimulus energy into a meaningful understanding –Each sense converts energy into awareness.

Perception of stimuli Option A.3. Receptors detect changes in the environment. List and describe the types of specialized receptors in humans. a. Mechanoreceptors-

Sensation and Perception Sensation: your window to the world Perception: interpreting what comes in your window.

CHAPTER 10 Vision and visual perception Form Vision.

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

Psychology 210 Lecture 4 Kevin R Smith.

Perceptual Constancies

Early Processing in Biological Vision

THE VISUAL SYSTEM.

Ch 6: The Visual System pt 2

VISION Module 18.

Optic Nerve Projections

Mind, Brain & Behavior Wednesday February 12, 2003.

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

Sensation & Perception

Fundamentals of Sensation and Perception

Central visual processing

Outline Announcements Human Visual Information Processing

Eye: Retina and Neural Mechanisms.

Duplex retina First instance of vision as ‘multiple specialized systems that operate in parallel’ Partitions for sensitivity (rods) and resolution (cones).

Presentation transcript:

Visual Sensation & Perception How do we see?

Structure of the eye

The Retina

Visual Receptors Rods –Slowly adapting –Black & White vision –120 million; None in fovea Cones –Rapidly adapting –Color vision –5 million; 50,000 in fovea

Retinal Ganglion cells Gather information from many rods and cones across an area of the retina. –How many rods and cones depends on the size of the ganglion cell’s receptive field –The closer to the fovea, the smaller the receptive field. Project out of the eye through the optic nerve, creating a blind spot. 1 million retinal ganglion cells (receiving signals from 125 million receptors).

Receptive fields of retinal ganglion cells Center-surround –Most are excitatory center, inhibitory surround. –Some are the opposite

Out of the retina Signals from the two eyes cross over to the opposite brain hemisphere at the optic chiasm. –Not all signals from an eye go to contra-lateral hemisphere. –Which hemisphere the signal goes to is based on which visual hemifield the ganglion cell receives information from.

Into the brain Ganglion cells synapse in the lateral geniculate nucleus (LGN) of the thalamus. For comparison, the auditory nerve synapses in the medial geniculate nucleus. The LGN divides the signals into layers depending on which eye they come from, and whether they come from the fovea or not. 1, 4, & 6 from the contralateral eye; 2, 3, and 5 from the ipsilateral eye. 1 and 2 from the fovea. 400,000 cells leave the LGN

V1 From the LGN, the signals are sent to area V1 in the very back of the occipital lobe. Signals are organized into a retinotopic map based on where on the retina they come from, and which eye they come from.

Feature detectors in V1 The retinotopic map is not simply a light/dark detector. Signals are beginning to be combined into simple feature detectors that can detect lines at various orientations. All of the feature detectors for a particular area of the retina are anatomically organized into a column. A hypercolumn is two columns from corresponding parts of both retinas.

Beyond V1 From V1, signals go to area V2 where the combine into more complex features (corners and simple shapes). After V2, the signal splits into two streams of information. –The what stream passes through V3 (which does color detection) into the temporal lobe. –The where stream passes through V4 (which aids with motion detection) into the parietal lobe.