Michael DeWeese: Difference between revisions

Revision as of 20:29, 28 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:

k. P.R. Zulkowski and M.R. DeWeese. Optimal entropy production. (in preparation)

j. J. Sohl-Dickstein, S. Teng, C. Rodgers, M.R. DeWeese, and N. Harper. A device for human ultrasonic echolocation. (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)

g. S. Marzen, J. Zylberberg, and M.R. DeWeese. 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).

Submitted manuscripts:

e. P.R. Zulkowski and M.R. DeWeese. Optimal finite-time erasure of a classical bit. (submitted)

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

c. C. Rodgers and M.R. DeWeese. Neural correlates of task switching in prefrontal cortex and primary auditory cortex in a novel stimulus selection task for rodents. (submitted).

b. B. Albanna, C. Hillar, J. Sohl-Dickstein, and M.R. DeWeese. Minimum and maximum entropy solutions for binary systems with known means and pairwise correlations. (submitted).

a. A.j. Apicella, M. Dastjerdi, and M.R. DeWeese. Synaptic mechanisms that contribute to spatial tuning in primary auditory cortex. (submitted).

All publications:

31. P.R. Zulkowski, D.A. Sivak, and M.R. DeWeese. Optimal control of transitions between nonequilibrium steady states. Public Library of Science ONE (in press)

30. J. Zylberberg and M.R. DeWeese. Sparse coding models can exhibit decreasing sparseness while learning sparse codes for natural images. Public Library of Science Computational Biology. 9(8):e1003182 (2013).

29. T. Hromádka, A.M. Zador, and M.R. DeWeese. Up-states are rare in awake auditory cortex. Journal of Neurophysiology. 109(8):1989-95. (2013).

28. P. King, J. Zylberberg, and M.R. DeWeese. Inhibitory interneurons decorrelate excitatory cells to drive sparse code formation in a spiking model of V1. Journal of Neuroscience 33(13):5475–85 (2013).

27. J. Zylberberg, D. Pfau, and M.R. DeWeese. Dead leaves and the dirty ground: Low-level image statistics in transmissive and occlusive imaging environments. Physical Review E. 86:066112 (2012).

26. P.R. Zulkowski, D.A. Sivak, G.E. Crooks, and M.R. DeWeese. The geometry of thermodynamic control. Physical Review E. 86(4 Pt 1):041148 (2012).

25. N. Carlson, V.L. Ming, and M.R. DeWeese. Sparse codes for speech predict spectrotemporal receptive fields in the inferior colliculus. Public Library of Science Computational Biology. 7(10):e1002250 (2012).

24. J. Sohl-Dickstein, P. Battaglino, and M.R. DeWeese. New method for parameter estimation in probabilistic models: Minimum probability flow. Physical Review Letters. 107(22):220601 (2011).

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).

22. J. Zylberberg, J.T. Murphy, and M.R. DeWeese. A sparse coding model with synaptically local plasticity and spiking neurons can account for the diverse shapes of V1 simple cell receptive fields. Public Library of Science Computational Biology. 7(10):e1002250 (2011).

21. J. Zylberberg, and M.R. DeWeese. How should prey animals respond to uncertain threats? Frontiers in Computational Neuroscience 5:20. doi: 10.3389/fncom.2011.00020 (2011).

20. M.A. Olshausen and M.R. DeWeese. Applied mathematics: The statistics of style. Nature 463(7284), 1027-1028 (2010).

19. Y. Yang, M.R. DeWeese, G. Otazu, and A.M. Zador. Millisecond-scale differences in neural activity in auditory cortex can drive decisions. Nature Neuroscience 11, 1262-1263 (2008).

18. T. Hromadka, M.R. DeWeese, and A.M. Zador. Sparse representation of sounds in the unanesthetized auditory cortex. PLoS Biol. 6, 124-137 (2008).

17. M.R. DeWeese. Whole-Cell Recording In Vivo. Chapter 6 in Current Protocols in Neuroscience. John Wiley & Sons, Inc., pp. 6.22.1-15 (2007).

16. M.R. DeWeese and A.M. Zador. Non-Gaussian membrane potential dynamics imply sparse, synchronous activity in auditory cortex. J. Neuroscience 26(47), 12206-12218 (2006).

15. M.R. DeWeese and A.M. Zador. Neurobiology: Efficiency Measures. Nature 439(7079), 920-921 (2006).

14. M.R. DeWeese, T. Hromádka, and A.M. Zador. Reliability and representational bandwidth in auditory cortex. Neuron 48, 479-588 (2005).

13. M.R. DeWeese and A.M. Zador. Neural gallops across auditory streams. Neuron 48, 5-7 (2005).

12. M.R. DeWeese and A.M. Zador. Shared and private variability in the auditory cortex. J. Neurophysiol. 92, 1840-1855 (2004).

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).

10. M.R. DeWeese, M. Wehr, and A.M. Zador. Binary spiking in auditory cortex. J. Neurosci. 23, 7940-7949 (2003).

9. M.R. DeWeese. An optimal preparation for studying optimization. Neuron 26, 546-548 (2000).

8. M.R. DeWeese and M. Meister. How to measure the information gained from one symbol. Network 10, 325-340 (1999).

7. G. Buracas, A.M. Zador, M.R. DeWeese, and T. Albright. Efficient discrimination of temporal patterns by motion-sensitive neurons in primate visual cortex. Neuron 20, 959-969 (1998).

6. M.R. DeWeese and A. Zador. Asymmetric dynamics in optimal variance adaptation. Neural Computation 10, 1179-1202 (1998).

5. M.R. DeWeese. Optimization principles for the neural code. Network 7, 325-331 (1996).

4. M. DeWeese. Optimization principles for the neural code. In Advances in Neural Information Processing Systems. MIT Press, Cambridge, MA, Vol. 8, p. 281 (1996).

3. W. Bialek and M. DeWeese. Random switching and optimal processing in the perception of ambiguous signals. Phys. Rev. Lett. 74, 3077-3080 (1995).

2. M. DeWeese and W. Bialek. Information flow in sensory neurons. Il Nuovo Cimento A17, 733 (1995).

1. W. Bialek, M. DeWeese, F. Rieke, and D. Warland. Bits and brains: information flow in the nervous system. Physica A 200, 581-593 (1993).

@@ Line 3: / Line 3: @@
 '''Selected manuscripts in preparation:'''
-*l. P.R. Zulkowski and M.R. DeWeese. Optimal entropy production. (in preparation)
+*k. P.R. Zulkowski and M.R. DeWeese. Optimal entropy production. (in preparation)
-*k. J. Sohl-Dickstein, S. Teng, C. Rodgers, M.R. DeWeese, and N. Harper. [https://redwood.berkeley.edu/w/images/f/f7/SohlDickstein_et_al_echolocation_for_the_blind_icme_preprint.pdf  A device for human ultrasonic echolocation.] (in preparation)
+*j. J. Sohl-Dickstein, S. Teng, C. Rodgers, M.R. DeWeese, and N. Harper. [https://redwood.berkeley.edu/w/images/f/f7/SohlDickstein_et_al_echolocation_for_the_blind_icme_preprint.pdf  A device for human ultrasonic echolocation.] (in preparation)
-*j. 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)
-*i. 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)
+*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)
-*h. 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)
+*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)
-*g.  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).
+*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:'''
-*f. P.R. Zulkowski and M.R. DeWeese. [https://redwood.berkeley.edu/w/images/b/b3/Zulkowski_DeWeese_optimal_erasure_1_bit_preprint.pdf Optimal finite-time erasure of a classical bit.] (submitted)
+*e. P.R. Zulkowski and M.R. DeWeese. [https://redwood.berkeley.edu/w/images/b/b3/Zulkowski_DeWeese_optimal_erasure_1_bit_preprint.pdf Optimal finite-time erasure of a classical bit.] (submitted)
-*e. J. Sohl-Dickstein, M. Mudigonda, M.R. DeWeese.  [https://redwood.berkeley.edu/w/images/2/2b/SohlDickstein_Mudigonda_DeWeese_Sampling_Without_Detailed_Ballance_preprint.pdf Hamiltonian Monte Carlo Without Detailed Balance.] (submitted)
+*d. J. Sohl-Dickstein, M. Mudigonda, M.R. DeWeese.  [https://redwood.berkeley.edu/w/images/2/2b/SohlDickstein_Mudigonda_DeWeese_Sampling_Without_Detailed_Ballance_preprint.pdf 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).
+*c. 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).
-*c. P.R. Zulkowski, D.A. Sivak, and M.R. DeWeese. [https://redwood.berkeley.edu/w/images/b/bb/Zulkowski_Sivak_DeWeese_Optimal_Control_Y_value_032713_preprint.pdf Optimal control of transitions between nonequilibrium steady states.] (submitted)
 *b.  B. Albanna, C. Hillar, J. Sohl-Dickstein, and M.R. DeWeese.  [https://redwood.berkeley.edu/w/images/8/8a/Albanna_Hillar_SohlDickstein_DeWeese_min_entropy_preprint.pdf Minimum and maximum entropy solutions for binary systems with known means and pairwise correlations.] (submitted).
@@ Line 30: / Line 28: @@
 '''All publications:'''
+*31. P.R. Zulkowski, D.A. Sivak, and M.R. DeWeese. [https://redwood.berkeley.edu/w/images/b/bb/Zulkowski_Sivak_DeWeese_Optimal_Control_Y_value_032713_preprint.pdf Optimal control of transitions between nonequilibrium steady states.] Public Library of Science ONE (in press)
 *30.   J. Zylberberg and M.R. DeWeese.  [https://redwood.berkeley.edu/w/images/6/62/Zylberberg_DeWeese_Decreasing_Sparseness_During_Development_PLoS_CB_2013_reprint.pdf Sparse coding models can exhibit decreasing sparseness while learning sparse codes for natural images.] Public Library of Science Computational Biology. 9(8):e1003182 (2013).

Michael DeWeese: Difference between revisions

Revision as of 20:29, 28 October 2013

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