Title: Active Vision
1 Active Vision
Carol Colby Rebecca Berman Cathy Dunn Chris
Genovese Laura Heiser Eli Merriam Kae
Nakamura Department of Neuroscience Center for
the Neural Basis of Cognition University of
Pittsburgh Department of Statistics Carnegie
Mellon University
2Why does the world stay still when we move
our eyes?
Hermann von Helmholtz Treatise on Physiological
Optics, 1866
Effort of will
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4- Remapping in monkey area LIP and extrastriate
visual cortex
5- Remapping in monkey area LIP and extrastriate
visual cortex - 2) Remapping in split-brain monkeys
-
- Behavior
- Physiology
6- Remapping in monkey area LIP and extrastriate
visual cortex - 2) Remapping in split-brain monkeys
-
- Behavior
- Physiology
- 3) Remapping in human cortex
- Parietal cortex
- Striate and extrastriate visual cortex
- Remapping in a split brain human
7LIP memory guided saccade
Stimulus On
Saccade
8Stimulus appears outside of RF
Saccade moves RF to stimulus location
9Single step task
10Spatial updating or remapping The brain combines
visual and corollary discharge signals to create
a representation of space that takes our eye
movements into account
11LIP Summary Area LIP neurons encode attended
spatial locations.
12- LIP Summary
- Area LIP neurons encode attended spatial
locations. - The spatial representation of an attended
location is remapped when the eyes move.
13- LIP Summary
- Area LIP neurons encode attended spatial
locations. - The spatial representation of an attended
location is remapped when the eyes move. - Remapping is initiated by a corollary discharge
of the eye movement command.
14- LIP Summary
- Area LIP neurons encode attended spatial
locations. - The spatial representation of an attended
location is remapped when the eyes move. - Remapping is initiated by a corollary discharge
of the eye movement command. - Remapping produces a representation that is
oculocentric a location is represented in the
coordinates of the movement needed to acquire the
location.
15- LIP Summary
- Area LIP neurons encode attended spatial
locations. - The spatial representation of an attended
location is remapped when the eyes move. - Remapping is initiated by a corollary discharge
of the eye movement command. - Remapping produces a representation that is
oculocentric a location is represented in the
coordinates of the movement needed to acquire the
location. - Remapping allows humans and monkeys to perform a
spatial memory task accurately.
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17LIP
V3A
FEF
V3
V2
V1
SC
LGN
Oculomotor System
Retina
18Stimulus appears outside of RF
Saccade moves RF to stimulus location
19Stimulus alone control
Saccade alone control
20Single step task
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22- Extrastriate Summary
- Remapping occurs at early stages of the visual
hierarchy. -
23- Extrastriate Summary
- Remapping occurs at early stages of the visual
hierarchy. - Corollary discharge has an impact far back into
the system. -
24- Extrastriate Summary
- Remapping occurs at early stages of the visual
hierarchy. - Corollary discharge has an impact far back into
the system. - Remapping implies widespread connectivity in
which many neurons have rapid access to
information well beyond the classical receptive
field. -
-
25- Extrastriate Summary
- Remapping occurs at early stages of the visual
hierarchy. - Corollary discharge has an impact far back into
the system. - Remapping implies widespread connectivity in
which many neurons have rapid access to
information well beyond the classical receptive
field. - Vision is an active process of building
representations. -
26- Remapping in monkey area LIP and extrastriate
visual cortex - 2) Remapping in split-brain monkeys
-
- Behavior
- Physiology
- 3) Remapping in human cortex
- Parietal cortex
- Striate and extrastriate visual cortex
- Remapping in a split brain human
27Stimulus appears outside of RF
Saccade moves RF to stimulus location
28What is the brain circuit that produces
remapping?
29The obvious pathway for visual signals forebrain
commissures
30Are the forebrain commissures necessary for
updating visual signals across the vertical
meridian? Behavior in double step task
Physiology in single step and double step task
31 32 33Transfer of visual signals
WITHIN
T2
T1
T2
34WITHIN
T2
T1
35WITHIN
T2
T1
T2
T2
T2
36VISUAL-ACROSS
WITHIN
T2
T1
T2
37Is performance impaired on visual-across
sequences in split-brain monkeys?
WITHIN
VISUAL-ACROSS
T2
T2
T1
T1
T2
T2
T2
T2
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39Day 1 Initial impairment for visual-across
Monkey C
40TRIALS
1-10
41First day saccade endpoints
Vertical eye position (degrees)
Horizontal eye position (degrees)
42Last day saccade endpoints
Monkey C
Vertical eye position (degrees)
Monkey E
Monkey E
Horizontal eye position (degrees)
43Are the forebrain commissures necessary for
updating spatial information across the vertical
meridian?
44Are the forebrain commissures necessary for
updating spatial information across the vertical
meridian? No. The FC are the primary route but
not the only route.
45Are the forebrain commissures necessary for
updating spatial information across the vertical
meridian? No. The FC are the primary route but
not the only route. What are LIP neurons doing?
46Stimulus appears outside of RF
Saccade moves RF to stimulus location
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48Population activity in area LIP
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50Split Brain Monkey Summary The forebrain
commissures normally transmit remapped visual
signals across the vertical meridian but they are
not required.
51Split Brain Monkey Summary The forebrain
commissures normally transmit remapped visual
signals across the vertical meridian but they are
not required. Single neurons in area LIP
continue to encode remapped stimulus traces in
split-brain animals.
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54- Remapping in monkey area LIP and extrastriate
visual cortex - 2) Remapping in split-brain monkeys
-
- Behavior
- Physiology
- 3) Remapping in human cortex
- Parietal cortex
- Striate and extrastriate visual cortex
- Remapping in a split brain human
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64Functional Imaging Predictions 1) Robust
activation in cortex ipsilateral to the stimulus.
65- Functional Imaging Predictions
- 1) Robust activation in cortex ipsilateral to the
stimulus. - 2) Ipsilateral activation should be smaller than
the contralateral visual response.
66- Functional Imaging Predictions
- 1) Robust activation in cortex ipsilateral to the
stimulus. - 2) Ipsilateral activation should be smaller than
the contralateral visual response. - 3) It should not be attributable to the stimulus
alone or to the saccade alone.
67- Functional Imaging Predictions
- 1) Robust activation in cortex ipsilateral to the
stimulus. - 2) Ipsilateral activation should be smaller than
the contralateral visual response. - 3) It should not be attributable to the stimulus
alone or to the saccade alone. - 4) Ipsilateral activation should occur around the
time of the saccade.
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71 Contralateral Visual Response
72Ipsilateral Remapped Response
73Ipsilateral Remapped Response
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76Visual and Remapped Responses
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85- Human Parietal Imaging Summary
- Remapping in humans produces activity in parietal
cortex ipsilateral to the visual stimulus. -
86- Human Parietal Imaging Summary
- Remapping in humans produces activity in parietal
cortex ipsilateral to the visual stimulus. - Remapped activity is lower amplitude than visual
activity. -
87- Human Parietal Imaging Summary
- Remapping in humans produces activity in parietal
cortex ipsilateral to the visual stimulus. - Remapped activity is lower amplitude than visual
activity. - It cannot be attributed to the stimulus or the
saccade alone. -
88- Human Parietal Imaging Summary
- Remapping in humans produces activity in parietal
cortex ipsilateral to the visual stimulus. - Remapped activity is lower amplitude than visual
activity. - It cannot be attributed to the stimulus or the
saccade alone. - It occurs in conjunction with the eye movement.
89- Remapping in monkey area LIP and extrastriate
visual cortex - 2) Remapping in split-brain monkeys
-
- Behavior
- Physiology
- 3) Remapping in human cortex
- Parietal cortex
- Striate and extrastriate visual cortex
- Remapping in a split brain human
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98Contralateral Visual Response
99Ipsilateral Remapped Response
100Remapping in Multiple Visual Areas
101- Remapping in monkey area LIP and extrastriate
visual cortex - 2) Remapping in split-brain monkeys
-
- Behavior
- Physiology
- 3) Remapping in human cortex
- Parietal cortex
- Striate and extrastriate visual cortex
- Remapping in a split brain human
102 Intact Subjects
Split Brain Subject
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105Strength of Parietal Responses in Split Brain
and Intact Subjects
106- Human Imaging Summary
- Remapping in humans produces activity in the
hemisphere ipsilateral to the stimulus. -
107- Human Imaging Summary
- Remapping in humans produces activity in the
hemisphere ipsilateral to the stimulus. - Remapped activity is present in human parietal,
extrastriate and striate cortex. -
108- Human Imaging Summary
- Remapping in humans produces activity in the
hemisphere ipsilateral to the stimulus. - Remapped activity is present in human parietal,
extrastriate and striate cortex. - Remapped visual signals are more prevalent at
higher levels of the visual system hierarchy. -
109- Human Imaging Summary
- Remapping in humans produces activity in the
hemisphere ipsilateral to the stimulus. - Remapped activity is present in human parietal,
extrastriate and striate cortex. - Remapped visual signals are more prevalent at
higher levels of the visual system hierarchy. - Remapping occurs in parietal and visual cortex
in a split brain human subject.
110Conclusions Remapping of visual signals is
widespread in monkey cortex.
111- Conclusions
- Remapping of visual signals is widespread in
monkey cortex. - Split-brain monkeys are able to remap visual
signals across the vertical meridian.
112- Conclusions
- Remapping of visual signals is widespread in
monkey cortex. - Split-brain monkeys are able to remap visual
signals across the vertical meridian. - Remapped visual signals are present in area LIP
in split-brain monkeys.
113- Conclusions
- Remapping of visual signals is widespread in
monkey cortex. - Split-brain monkeys are able to remap visual
signals across the vertical meridian. - Remapped visual signals are present in area LIP
in split-brain monkeys. - Remapped visual signals are robust in human
parietal and visual cortex.
114- Conclusions
- Remapping of visual signals is widespread in
monkey cortex. - Split-brain monkeys are able to remap visual
signals across the vertical meridian. - Remapped visual signals are present in area LIP
in split-brain monkeys. - Remapped visual signals are robust in human
parietal and visual cortex. - In a split-brain human, remapped visual signals
are found in parietal and visual cortex.
115- Conclusions
- Remapping of visual signals is widespread in
monkey cortex. - Split-brain monkeys are able to remap visual
signals across the vertical meridian. - Remapped visual signals are present in area LIP
in split-brain monkeys. - Remapped visual signals are robust in human
parietal and visual cortex. - In a split-brain human, remapped visual signals
are found in parietal and visual cortex. - Vision is an active process of building
representations from sensory, cognitive and motor
signals.
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118Learning? Or a monkey trick?
119no monkey tricks..
120Both monkeys really update the visual
representation
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123Magnitude of Remapped Response
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