Non-rigid motion perception from optic flow

Interest in the processing of optic flow has increased recently in both the neurophysiological and the psychophysical communities. We have designed a neural network model of the visual motion pathway in higher mammals that detects the direction of heading from optic flow. The model is a neural implementation of the subspace algorithm introduced by Heeger and Jepson (1990). We have tested the network in simulations that are closely related to psychophysical and neurophysiological experiments and show that our results are consistent with recent data from both fields. The network reproduces some key properties of human ego-motion perception. At the same time, it produces neurons that are selective for different components of ego-motion flow fields, such as expansions and rotations. These properties are reminiscent of a subclass of neurons in cortical area MSTd, the triple-component neurons. We propose that the output of such neurons could be used to generate a computational map of heading directions in or beyond MST.

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Visually mediated eye movements regulate the capture of optic flow in self-motion perception

Experimental Brain Research ◽

10.1007/s00221-009-2137-2 ◽

2009 ◽

Vol 202 (2) ◽

pp. 355-361 ◽

Cited By ~ 16

Author(s):

Juno Kim ◽

Stephen Palmisano

Keyword(s):

Eye Movements ◽

Motion Perception ◽

Optic Flow ◽

Self Motion

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How Optic Flow and Inertial Cues Improve Motion Perception

Cold Spring Harbor Symposia on Quantitative Biology ◽

10.1101/sqb.2014.79.024638 ◽

2014 ◽

Vol 79 ◽

pp. 141-148 ◽

Cited By ~ 4

Author(s):

Dora E. Angelaki

Keyword(s):

Motion Perception ◽

Optic Flow ◽

Inertial Cues

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Combining biological motion perception with optic flow analysis for self-motion in crowds

Journal of Vision ◽

10.1167/jov.20.9.7 ◽

2020 ◽

Vol 20 (9) ◽

pp. 7

Author(s):

Anna-Gesina Hülemeier ◽

Markus Lappe

Keyword(s):

Motion Perception ◽

Optic Flow ◽

Biological Motion ◽

Flow Analysis ◽

Biological Motion Perception ◽

Self Motion

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Drifting while stepping in place in old adults: Association of self-motion perception with reference frame reliance and ground optic flow sensitivity

Neuroscience ◽

10.1016/j.neuroscience.2017.01.044 ◽

2017 ◽

Vol 347 ◽

pp. 134-147 ◽

Cited By ~ 4

Author(s):

Catherine P. Agathos ◽

Delphine Bernardin ◽

Konogan Baranton ◽

Christine Assaiante ◽

Brice Isableu

Keyword(s):

Reference Frame ◽

Motion Perception ◽

Optic Flow ◽

Old Adults ◽

Flow Sensitivity ◽

Self Motion ◽

Stepping In Place

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Blindsight Modulation of Motion Perception

Journal of Cognitive Neuroscience ◽

10.1162/089892902760807186 ◽

2002 ◽

Vol 14 (8) ◽

pp. 1174-1183 ◽

Cited By ~ 8

Author(s):

James M. Intriligator ◽

Ruiman Xie ◽

Jason J. S. Barton

Keyword(s):

Motion Perception ◽

Optic Flow ◽

Reaction Times ◽

Similar Efficacy ◽

Forced Choice ◽

Flow Modulation ◽

Residual Vision ◽

Peripheral Cues ◽

Residual Motion ◽

Perceptual Abilities

Monkey data suggest that of all perceptual abilities, motion perception is the most likely to survive striate damage. The results of studies on motion blindsight in humans, though, are mixed. We used an indirect strategy to examine how responses to visible stimuli were modulated by blind-field stimuli. In a 26-year-old man with focal striate lesions, discrimination of visible optic flow was enhanced about 7% by blind-field flow, even though discrimination of optic flow in the blind field alone (the direct strategy) was at chance. Pursuit of an imagined target using peripheral cues showed reduced variance but not increased gain with blind-field cues. Preceding blind-field prompts shortened reaction times to visible targets by about 10 msec, but there was no attentional crowding of visible stimuli by blind-field distractors. A similar efficacy of indirect blind-field optic flow modulation was found in a second patient with residual vision after focal striate damage, but not in a third with more extensive medial occipito-temporal damage. We conclude that indirect modulatory strategies are more effective than direct forced-choice methods at revealing residual motion perception after focal striate lesions.

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Cerebellar tDCS alters the perception of optic flow

10.1101/2021.02.15.431326 ◽

2021 ◽

Author(s):

Jean-François Nankoo ◽

Christopher R Madan ◽

Omar Medina ◽

Tyler Makepeace ◽

Christopher L. Striemer

Keyword(s):

Motion Perception ◽

Optic Flow ◽

Neuronal Excitability ◽

Large Field ◽

Motion Discrimination ◽

Non Invasive ◽

Flow Motion ◽

Cerebellar Tdcs ◽

Cathodal Stimulation

AbstractStudies have shown that the cerebellar vermis is involved in the perception of motion. However, it is unclear how the cerebellum influences motion perception. tDCS is a non-invasive brain stimulation technique that can reduce (through cathodal stimulation) or increase neuronal excitability (through anodal stimulation). To explore the nature of the cerebellar involvement on large-field global motion perception (i.e., optic flow-like motion), we applied tDCS on the cerebellar midline while participants performed an optic flow motion discrimination task. Our results show that anodal tDCS improves discrimination threshold for optic flow perception, but only for left-right motion in contrast to up-down motion discrimination. This result was evident within the first 10 minutes of stimulation and was also found post-stimulation. Cathodal stimulation did not have any significant effects on performance in any direction. The results show that discrimination of planar optic flow can be improved with tDCS of the cerebellar midline and provide further support for the role of the human midline cerebellum in the perception of optic flow.

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Activity Strength within Optic Flow-Sensitive Cortical Regions Is Associated with Visual Path Integration Accuracy in Aged Adults

Brain Sciences ◽

10.3390/brainsci11020245 ◽

2021 ◽

Vol 11 (2) ◽

pp. 245

Author(s):

Lauren Zajac ◽

Ronald Killiany

Keyword(s):

Motion Perception ◽

Optic Flow ◽

Path Integration ◽

Visual Motion ◽

Spatial Navigation ◽

Motion Processing ◽

Global Pattern ◽

Age Related ◽

Cortical Regions ◽

Self Motion

Spatial navigation is a cognitive skill fundamental to successful interaction with our environment, and aging is associated with weaknesses in this skill. Identifying mechanisms underlying individual differences in navigation ability in aged adults is important to understanding these age-related weaknesses. One understudied factor involved in spatial navigation is self-motion perception. Important to self-motion perception is optic flow–the global pattern of visual motion experienced while moving through our environment. A set of optic flow-sensitive (OF-sensitive) cortical regions was defined in a group of young (n = 29) and aged (n = 22) adults. Brain activity was measured in this set of OF-sensitive regions and control regions using functional magnetic resonance imaging while participants performed visual path integration (VPI) and turn counting (TC) tasks. Aged adults had stronger activity in RMT+ during both tasks compared to young adults. Stronger activity in the OF-sensitive regions LMT+ and RpVIP during VPI, not TC, was associated with greater VPI accuracy in aged adults. The activity strength in these two OF-sensitive regions measured during VPI explained 42% of the variance in VPI task performance in aged adults. The results of this study provide novel support for global motion processing as a mechanism underlying visual path integration in normal aging.

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