Michael DeWeese: Difference between revisions

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*i. M. Leonard and M.R. DeWeese. A subpopulation of neurons in prefrontal cortex encode recent actions in a working memory task but only during uncued trials. (in preparation)  
*i. M. Leonard and M.R. DeWeese. A subpopulation of neurons in prefrontal cortex encode recent actions in a working memory task but only during uncued trials. (in preparation)  


*h. M. Mudigonda, J. Sohl-Dickstein, M.R. DeWeese, S. Ganguli, and B. OlshausenReduced Flipping in Hamiltonian Markov Chain Monte Carlo algorithms. (in preparation)
*h. N. Carlson, V.L. Ming, and M.R. DeWeese.  Probe stimuli affect receptive field estimation of model auditory neurons optimized to represent speech efficiently. (in preparation)


*g. N. Carlson, V.L. Ming, and M.R. DeWeese.  Probe stimuli affect receptive field estimation of model auditory neurons optimized to represent speech efficiently. (in preparation)
*g. S. Marzen, J. Zylberberg, and M.R. DeWeese.  [https://redwood.berkeley.edu/w/images/c/ca/Marzen_Zylberberg_DeWeese_BinocularDisparity_R7a_1-28-2013-2_preprint.pdf The effect of natural scene statistics and oculomotor strategy on binocular disparity and ocular dominance maps.] (in preparation)


*f. S. Marzen, J. Zylberberg, and M.R. DeWeese.  [https://redwood.berkeley.edu/w/images/c/ca/Marzen_Zylberberg_DeWeese_BinocularDisparity_R7a_1-28-2013-2_preprint.pdf The effect of natural scene statistics and oculomotor strategy on binocular disparity and ocular dominance maps.] (in preparation)
*f. S. Corinaldi and M.R. DeWeese.  A network model of task switching optimized to minimize errors predicts several counterintuitive features of human behavioral data. (in preparation).


*e.  S. Corinaldi and M.R. DeWeese.  A network model of task switching optimized to minimize errors predicts several counterintuitive features of human behavioral data. (in preparation).
'''Submitted manuscripts:'''


'''Submitted manuscripts:'''
*e. J. Sohl-Dickstein, M. Mudigonda, M.R. DeWeese.  Hamiltonian Monte Carlo Without Detailed Balance. (submitted)


*d. C. Rodgers and M.R. DeWeese.  [https://redwood.berkeley.edu/w/images/e/e2/Rodgers_DeWeese_neural_correlates_of_task_switching_in_mPFC_and_A1_preprint.pdf Neural correlates of task switching in prefrontal cortex and primary auditory cortex in a novel stimulus selection task for rodents.] (submitted).   
*d. C. Rodgers and M.R. DeWeese.  [https://redwood.berkeley.edu/w/images/e/e2/Rodgers_DeWeese_neural_correlates_of_task_switching_in_mPFC_and_A1_preprint.pdf Neural correlates of task switching in prefrontal cortex and primary auditory cortex in a novel stimulus selection task for rodents.] (submitted).   

Revision as of 16:55, 11 October 2013

Here is my short CV and below is my publication list including some preprints. Most papers are available here as PDFs.

Selected manuscripts in preparation:

  • i. M. Leonard and M.R. DeWeese. A subpopulation of neurons in prefrontal cortex encode recent actions in a working memory task but only during uncued trials. (in preparation)
  • h. N. Carlson, V.L. Ming, and M.R. DeWeese. Probe stimuli affect receptive field estimation of model auditory neurons optimized to represent speech efficiently. (in preparation)
  • f. S. Corinaldi and M.R. DeWeese. A network model of task switching optimized to minimize errors predicts several counterintuitive features of human behavioral data. (in preparation).

Submitted manuscripts:

  • e. J. Sohl-Dickstein, M. Mudigonda, M.R. DeWeese. Hamiltonian Monte Carlo Without Detailed Balance. (submitted)

All publications:

  • 23. J. Sohl-Dickstein, P. Battaglino, and M.R. DeWeese. Minimum Probability Flow Learning. Proceedings of the 28th International Conference on Machine Learning (Bellevue, WA) (2011).
  • 11. M.R. DeWeese and A.M. Zador. Binary coding in auditory cortex. In Advances in Neural Information Processing Systems. MIT Press, Cambridge, MA, Vol. 15, 101 (2003).
  • 5. M.R. DeWeese. Optimization principles for the neural code. Network 7, 325-331 (1996).