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J. Anthony MovshonVision and visual development
I received my doctorate from Cambridge University, where I studied visual neurophysiology and psychophysics. I joined the Department of Psychology at New York University in 1975, and have remained here apart from a sabbatical year spent at Oxford University. In 1986, my laboratory moved to the Center for Neural Science.
My laboratory maintains active collaborations with other groups at NYU, including those of Michael Hawken, Lynne Kiorpes, and Eero Simoncelli. Click for my full cv, and my Google Scholar profile. You may also want to visit the Visual Neuroscience Laboratory web page. E-mail: movshon@nyu.edu Representative PublicationsGo here for a more complete list and downloads
M. Jazayeri and J. A. Movshon (2006). Optimal representation of sensory information by neural populations. Nature Neuroscience 9: 690-696.
N.C. Rust, V. Mante, E.P. Simoncelli and J.A. Movshon (2006). How MT cells analyze the motion of visual patterns. Nature Neuroscience 9: 1421-1431.
M. Jazayeri and J. A. Movshon (2007). A new perceptual illusion reveals mechanisms of sensory decoding. Nature 446: 912-915.
C. Tailby, N. J. Majaj and J. A. Movshon (2010). Binocular integration of pattern motion signals by MT neurons and by human observers. Journal of Neuroscience 30: 7344-7349.
Y. El-Shamayleh, L. Kiorpes, A. Kohn and J. A. Movshon (2010). Visual motion processing by neurons in area MT of macaque monkeys with experimental amblyopia. Journal of Neuroscience 30: 12198-12209.
D. M. Levi, S. P. McKee and J. A. Movshon (2011). Visual deficits in anisometropia. Vision Research 51: 48-57.
A. B. A. Graf, A. Kohn, M. Jazayeri and J. A. Movshon (2011). Decoding the activity of neuronal populations in macaque primary visual cortex. Nature Neuroscience 14: 239-245.
J. H. Hedges, Y. Gartshteyn, A. Kohn, N. C. Rust, M. N. Shadlen, W. T. Newsome and J. A. Movshon (2011). Dissociation of neuronal and psychophysical responses to local and global motion. Current Biology 21: 2023-2028.
M. Jazayeri, P. Wallisch and J. A. Movshon (2012). Dynamics of macaque MT cell responses to grating triplets. Journal of Neuroscience 32: 8242-8253.
J. Freeman, C. M. Ziemba, D. J. Heeger, E. P. Simoncelli and J. A. Movshon (2013). A functional and perceptual signature of the second visual area in primates. Nature Neuroscience 16: 974-981.
Y. El-Shamayleh, R. D. Kumbhani, N. T. Dhruv and J. A. Movshon (2013). Visual response properties of V1 neurons projecting to V2 in macaque. Journal of Neuroscience 33: 16594-16605.
C. Shooner, L. E. Hallum, R. D. Kumbhani, C. M. Ziemba, V. Garcia-Marin, J. G. Kelly, N. J. Majaj, J. A. Movshon and L. Kiorpes (2015). Population representation of visual information in areas V1 and V2 of amblyopic macaques. Vision Research 114: 56-67.
R. L. Goris, E. P. Simoncelli and J. A. Movshon (2015). Origin and function of tuning diversity in macaque visual cortex. Neuron 88: 819-831.
C. M. Ziemba, J. Freeman, J. A. Movshon and E. P. Simoncelli (2016). Selectivity and tolerance for visual texture in macaque V2. Proceedings of the National Academy of Sciences, USA 113: E3140-3149.
R. L. Goris, C. M. Ziemba, G. M. Stine, E. P. Simoncelli and J. A. Movshon (2017). Dissociation of choice formation and choice-correlated activity in macaque visual cortex. Journal of Neuroscience 37: 5195-5203.
L. E. Hallum, C. Shooner, R. D. Kumbhani, V. Garcia-Marin, J. G. Kelly, N. J. Majaj, J. A. Movshon and L. Kiorpes (2017). Altered balance of receptive field excitation and suppression in visual cortex of amblyopic macaque monkeys. Journal of Neuroscience 37: 8216-8226.
C. M. Ziemba, J. Freeman, E. P. Simoncelli and J. A. Movshon (2018). Contextual modulation of sensitivity to naturalistic image structure in macaque V2. Journal of Neurophysiology 120: 409-420.
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All contents © New York University. All rights reserved. Revised: 02-Oct-2019 3:22PM |
I am interested in how the brain encodes and decodes visual information, and in the mechanisms that put that information to use in the control of behavior. My research concerns the function and development of the primate visual system, especially the visual areas of the cerebral cortex. My laboratory supports work on neurophysiology, neuroanatomy, psychophysics, and brain imaging; the main experimental tool is electrophysiological recording from single neurons in monkeys. We stress analytical and quantitative approaches to the study of visual receptive fields. Conceptually, much of this research draws on related work in visual psychophysics, and on computational approaches to understanding brain organization and visual processing.
My laboratory works mostly in two broad areas. The first concerns the functions of the visual areas of the primate cerebral cortex, with special emphasis on the roles of those areas in processing information about visual motion, form, and color. I am particularly interested in the relationships between visual signals in these areas, and the perceptual decisions and motor activity they support. The second concerns the functional development of the cortical visual system, and on the way that development is affected by forms of abnormal early visual experience that produce a visual system disorder known as amblyopia.