APS March Meeting 2017
Volume 62, Number 4
Monday–Friday, March 13–17, 2017;
New Orleans, Louisiana
Session K49: Physics of Neural Network Dynamics in the Brain
8:00 AM–11:00 AM,
Wednesday, March 15, 2017
Room: 396
Sponsoring
Units:
GSNP DBIO
Chair: Jin Wang, State University of New York at Stony Brook
Abstract ID: BAPS.2017.MAR.K49.3
Abstract: K49.00003 : Non-equilibrium physics of neural networks for leaning, memory and decision making: landscape and flux perspectives.
9:12 AM–9:48 AM
Preview Abstract
Abstract
Author:
Jin Wang
(Stony Brook University)
Cognitive behaviors are determined by underlying neural networks. Many brain
functions, such as learning and memory, can be described by attractor
dynamics. We developed a theoretical framework for global dynamics by
quantifying the landscape associated with the steady state probability
distributions and steady state curl flux, measuring the degree of
non-equilibrium through detailed balance breaking.
We found the dynamics and oscillations in human brains responsible for
cognitive processes and physiological rhythm regulations are determined not
only by the landscape gradient but also by the flux. We found that the flux
is closely related to the degrees of the asymmetric connections in neural
networks and is the origin of the neural
oscillations. The neural oscillation landscape shows a closed-ring attractor
topology. The landscape gradient attracts the network down to the ring. The
flux is responsible for coherent oscillations on the ring. We suggest the
flux may provide the driving force for associations among memories [1].
Both landscape and flux determine the kinetic paths and speed of decision
making. The kinetics and global stability of decision making are explored by
quantifying the landscape topography through the barrier heights and the
mean first passage time. The theoretical predictions are in agreement with
experimental observations: more errors occur under time pressure. We
quantitatively explored two mechanisms of the speed-accuracy tradeoff with
speed emphasis and further uncovered the tradeoffs among speed, accuracy,
and energy cost. Our results show an optimal balance among speed, accuracy,
and the energy cost in decision making. We uncovered possible mechanisms of
changes of mind and how mind changes improve performance in decision
processes. Our landscape approach can help facilitate an understanding of
the underlying physical mechanisms of cognitive processes and identify the
key elements in neural networks [2].
[1]. H. Yan, L. Zhao, L. Hu, X. Wang, E.K. Wang, J. Wang. Nonequilibrium
landscape theory of neural networks. Proc. Natl. Acad. Sci. USA E4185--E4194
(2013).
[2]. H. Yan, K. Zhang, J. Wang. Physical mechanism of mind changes and
tradeoffs among speed, accuracy, and energy cost in brain decision making-
Landscape, flux, and path perspectives.~Chin. Phys. B.~25(7), 078702.
(2016).
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2017.MAR.K49.3