It is widely accepted that the complex dynamics characteristic of recurrent
neural circuits contributes in a fundamental manner to brain function. Progress
has been slow in understanding and exploiting the computational power of
recurrent dynamics for two main reasons: nonlinear recurrent networks often
exhibit chaotic behavior and most known learning rules do not work in robust
fashion in recurrent networks. Here we address both these problems by
demonstrating how random recurrent networks (RRN) that initially exhibit
chaotic dynamics can be tuned through a supervised learning rule to generate
locally stable neural patterns of activity that are both complex and robust to
noise. The outcome is a novel neural network regime that exhibits both
transiently stable and chaotic trajectories. We further show that the recurrent
learning rule dramatically increases the ability of RRNs to generate complex
spatiotemporal motor patterns, and accounts for recent experimental data
showing a decrease in neural variability in response to stimulus onset

A Banerjee

A Litwin-Kumar

C Miall

C van Vreeswijk

CA Skarda

CV Buhusi

D Bueti

D Durstewitz

D Sussillo

DA Crowe

Dean V Buonomano

DJ Watts

DV Buonomano

E Pastalkova

EM Izhikevich

G Boffetta

G Fagiolo

H Jaeger

H Kantz

H Merchant

H Sompolinsky

J Coull

JF Medina

JJ Hopfield

JK Liu

JX Li

K Rajan

M London

M Monteforte

M Rabinovich

MA Long

MB Ahrens

MD Mauk

MM Churchland

MS Goldman

MS Matell

N Brunel

P Janssen

P Simen

RB Ivry

RHR Hahnloser

RM Church

Rodrigo Laje

S Ganguli

S Song

XJ Wang

Nature Neuroscience

English

arXiv

Crossref

Robust timing and motor patterns by taming chaos in recurrent neural networks

The brain’s ability to tell time and produce complex spatiotemporal motor patterns is critical to anticipating the next ring of a telephone or playing a musical instrument. One class of models proposes that these abilities emerge from dynamically changing patterns of neural activity generated within recurrent neural networks. However, the relevant dynamic regimes of recurrent networks are highly sensitive to noise, i.e., chaotic. We describe a firing rate model that tells time on the order of seconds and generates complex spatiotemporal patterns in the presence of high levels of noise. This is achieved through the tuning of the recurrent connections. The network operates in a novel dynamic regime that exhibits coexisting chaotic and locally stable trajectories. These stable patterns function as “dynamic attractors ” and provide a novel feature characteristic of biological systems: the ability to “return ” to the pattern being generated in the face of perturbations. Timing is a fundamental component of sensory and motor processing, learning, and cognition; yet, the neural mechanisms underlying temporal processing remain unknown1–3. On the scale of milliseconds and seconds a number of different mechanisms have bee

Dean V. Buonomano

CiteSeerX

Robust timing and motor patterns by taming chaos in recurrent neural networks. Nat. Neurosci. 16, 925–933. doi: 10.1038/ nn.3405

The brain's ability to tell time and produce complex spatiotemporal motor patterns is critical for anticipating the next ring of a telephone or playing a musical instrument. One class of models proposes that these abilities emerge from dynamically changing patterns of neural activity generated in recurrent neural networks. However, the relevant dynamic regimes of recurrent networks are highly sensitive to noise; that is, chaotic. We developed a firing rate model that tells time on the order of seconds and generates complex spatiotemporal patterns in the presence of high levels of noise. This is achieved through the tuning of the recurrent connections. The network operates in a dynamic regime that exhibits coexisting chaotic and locally stable trajectories. These stable patterns function as 'dynamic attractors' and provide a feature that is characteristic of biological systems: the ability to 'return' to the pattern being generated in the face of perturbations.Fil: Laje, Rodrigo. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Universidad Nacional de Quilmes. Departamento de Ciencia y Tecnología; Argentina. University of California at Los Angeles. School of Medicine. Department of Neurobiology; Estados UnidosFil: Buonomano, Dean V.. University of California at Los Angeles. School of Medicine. Department of Neurobiology; Estados Unido

Laje, Rodrigo

Buonomano, Dean V.

CONICET Digital

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