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The Human Visual System Vonikakis Vasilios, Antonios Gasteratos Democritus University of Thrace 2006 2006
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The Human Visual System Biological background Retina Visual Cortex V1, V2… Optic nerve light (ganglion cells)
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Ανθρώπινο Οπτικό Σύστημα The eye
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3 kinds of cones (long, medium, short) – color vision (only in bright light – photopic vision) Rods – achromatic vision (in dim light – scotopic vision) The photoreceptors
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Only one layer of photoreceptors Only one layer of photoreceptors Varying distribution of photoreceptors (Only L and M cones in the fovea, only rods in the periphery) Different ratios of photoreceptors between individuals (generally L>M>S) Hexagonal distribution of photoreceptors No refresh rate – parallel transmission of visual information to the brain Differences from a ccd
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What retina sees Day Night
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Output photoreceptors Ganglion cell Basic retinal circuit Ganglion cells are the only output of from the retina Digital output with an FM modulation (spikes)
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The number of photoreceptors that a ganglion cell “sees” and the kind of the connection Ganglion cells have antagonistic center-surround receptive field + -- Receptive field
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+-- Center-surround antagonism
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+ -- + -- + -- + -- nothing light No light light inhibition excitation Center-surround responses
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Ganglion cells are edge detectors – they respond only to changes and not to uniform areas By stimulating only the cells that detect differences, the HVS minimizes the number of active neurons Example: Instead of transmitting a sequence of long numbers e.g. 2003453, 2003453, 2003455, 2003451 it transmits only their differences: 0, 0, +2, -2 Center-surround : facts
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White paper in dim light reflects less light (is darker) than the black letters in bright light The absolute value of reflected light is not important By responding only to differences, ganglion cells prevent the white paper from being perceived as black Center-surround : advantage Dim light Bright light Bright light
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Kinds of Ganglion cells Biological background Photoreceptor mosaic B center - (R+G) surround R center - G surround G center - R surround (R+G+B) center - (R+G+B) surround Red-Green oponency Blue-Yellow oponency Achromatic opponency
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Midget ganglion cells Biological background
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Midget ganglion cells Midget ganglion multiplex 2 signals 1.Red-Green chromatic opponency 2.Achromatic high acuity (1 cone = 1 center of the receptive field)
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Parasol ganglion cells Parasol ganglion cells are: 1.Achromatic 2.Have 3 times greater receptive filed 3.Respond better to movement 2
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Bistratified ganglion cells Bistratified ganglion cells: 1.Carry the Blue – Yellow opponency 2.Have 3 times greater receptive filed 2
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Retinal output At least 8 independent and parallel mosaics of ganglion cells outputs scan the photoreceptors and transmit different information to the visual cortex
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The primary visual cortex V1 The visual cortex analyses the retinal output in 3 different and independent maps: 1.color 2.motion-depth 3.orientation of edges
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The primary visual cortex V1 The visual cortex analyses the retinal output in 3 different and independent maps: 1.color 2.motion-depth 3.orientation of edges
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Demultiplexing RG in cortex In every position of the visual field 4 different midget cells (from the 4 mosaics) are connected in couples Chromatic opponency is canceled (same colors to center and surround). Now only sensitive only to luminance increments Chromatic opponency is canceled (same colors to center and surround). Now only sensitive only to luminance decrements Center-surround antagonism is canceled (they are the same) Center-surround antagonism is canceled
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Cell types For every position of the visual field there are 8 different cells that detect chromatic and achromatic signals in 2 different scales
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Cell outputs original Red-Green opponency Blue-Yellow opponency Achromatic (dark-light)
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Double opponent cells Are formed by combinations of simple center-surround cells Are excited only by chromatic differences of a very specific color (color edges)
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Responses Double opponent cells respond only to very specific changes between certain hues (color edges) original
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Elongated receptive fields (formed by combinations of center- surround receptive fields) ~12 different orientations (every 15°) Detect edges of particular orientations only in a very specific position Simple Orientation cells
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Formed by combinations of simple orientation cells Detect edges of particular orientation anywhere in their receptive field Complex Orientation cells
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Orientation cells At every position of the visual field there are all possible orientations of an edge Every edge excites a particular orientation cell in a particular position of the visual cortex
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Hypercolumns For every position of the visual field, all cells are grouped into hyper columns Every hypercolumn is a complete and independent feature detector for a very small part of the visual field Every hypercolumn contains color cells, orientation cells, disparity cells, motion cells
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Hypercolumns Competition exists between cells of the same hypercolumn and between hypercolumns
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Association field Biological background Orientation cells prefer to be connected with others that favor the smooth continuity of contours Connection of orientation cells
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Smooth combinations emerge from the group of orientation cells This is the first step for contour perception Salient contours
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More complex cells code certain combinations of salient orientation cells Contour integration
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All the features (contours, colors, texture, depth) are being bind in one perception Binding is described by the Gestalt rules e.g. common fate rule, proximity rule, similarity rule etc. Feature binding
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There is a tendency to spatially diffuse strong signals over the weak ones This way, regions that do not have a strong feature ‘get’ one from a nearby region that has a strong one This way, regions that do not have a strong feature ‘get’ one from a nearby region that has a strong one Edges act like barriers that stop the diffusions of the signals There is filling-in for: TextureTexture ColorColorDisparity Filling-in the features
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Filling-in illusions
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shapecolortexturemotion Object space binding Binding to one percept
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What & Where stream
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Cell(s) for every object Finally there is one cell (or one population of cells) that respond only to a very specific object Every perception of an object (either vision triggered or mind triggered) activates these cells This ‘databank’ of cells is located at the inferior temporal cortex This ‘databank’ of cells is located at the inferior temporal cortex
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Inferior temporal cortex Inferior temporal cortex has columnar organization Many aspects of an object are stored in neighboring columns Similar objects are stored in neighboring rows
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Inferior temporal cortex Every object is stored in the object space in many rotated versions …but we are trained only to the versions we usually see…
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Attention models
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Thank you!
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