The research goal of James DiCarlo’s group is a computational understanding of the brain mechanisms that underlie object recognition. His group is currently focussed on understanding how transformations carried out by a series of neocortical processing stages — called the primate ventral visual stream — are effortlessly able to untangle object identity from other latent image variables such as object position, scale, and pose. He and his collaborators have shown that populations of neurons at the highest cortical visual processing stage (IT) rapidly (<200 ms) convey explicit representations of object identity, even in the face of naturally occurring image variability. His group has found that the ventral stream’s ability to accomplish this feat is rapidly reshaped by natural visual experience and they can now monitor the neuronal substrates of this learning online. This points the way to understanding how the visual system uses the statistics of the visual world to “learn” neuronal representations that automatically untangle object identity. He and his collaborators have also shown how carefully designed visual recognition tests can be used to discover new, high-performing bio-inspired algorithms, and to efficiently explore the hypothesis space of possible cortical algorithms. His group is currently using a combination of large-scale neurophysiology, brain imaging, optogenetic methods, and high-throughput computational simulations to understand the neuronal mechanisms and fundamental cortical computations that underlie the construction of these powerful image representations. They aim to use this understanding to inspire and develop new machine vision systems, to provide a basis for new neural prosthetics (brain-machine interfaces) to restore or augment lost senses, and to provide a foundation upon which the community can understand how high-level visual representation is altered in human conditions such as agnosia, autism and dyslexia.
McKnight Scholar Award in Neuroscience, McKnight Foundation, 2006-2009.
Surdna Research Foundation Award, MIT, 2005.
MIT School of Science Prize for Excellence in Undergraduate Teaching, 2005.
Pew Scholar in the Biomedical Sciences, 2002-2006.
Alfred P. Sloan Research Fellow, 2002.
N. Li, et al, "What response properties do individual neurons need to underlie position and clutter "invariant" object recognition?," J. Neurophysiol. vol. 102, no. 1, pp. 360-76, Jul. 2009.
J.J. DiCarlo and N. Li Too, "Unsupervised natural experience rapidly alters invariant object representation in visual cortex," Science, vol. 321, no. 5895, pp. 1502-7, Sept. 2008.
Associate Fellow Learning in Machines & Brains
Massachusetts Institute of TechnologyDepartment of Brain and Cognitive Sciences
PhD (Biomedical Engineering) John Hopkins University
B.S.E. (Biomedical Engineering) Northwestern University
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