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@INPROCEEDINGS{Ito:1031974,
author = {Ito, Junji and Oberste-Frielinghaus, Jonas and Kurth, Anno
and Grün, Sonja},
title = {{S}ynfire chains in random weight threshold unit network},
reportid = {FZJ-2024-05898},
year = {2024},
abstract = {Synfire chains have been postulated as a model for stable
propagation of synchronous spikes through the cortical
networks [1,2,3]. Synfire-chain-like activity can also be
found in spiking artificial neural networks trained for a
classification task [4]. Understanding the mechanism for
generating such activity would provide better insights into
the functioning of real brains and artificial neural
networks. Here we consider an analytically tractable network
of binary units to study the conditions for the emergence of
synchronous spikes and their stable propagation.Our network
is organized in layers of $N$ threshold units, each taking a
state $x\in\{0,1\}$ depending on its input $I$ as
$x=H(I-\theta)$ ($H$: Heaviside step function, $\theta$:
threshold). The connections from layer $l$ to $l+1$ are
represented by a matrix $W^l$, whose elements are Gaussian
IID random variables with mean 0 and variance $1/N$. States
of all units are initially set to 0. Then a fraction $P^1$
of layer 1 units are activated (their states set to 1) at
different timings. We interpret the state change of a unit
as a spike generation by that unit. The spikes generated in
layer $l$ are propagated to layer $l+1$ through the matrix
$W^l$, providing time-varying inputs to activate layer $l+1$
units and generate their spikes.Based on the formalism laid
out in [5], we derive a relation between the fraction
$p^l(t)$ and $p^{l+1}(t)$ of active units at time $t$ in
layer $l$ and $l+1$, respectively, as
$p^{l+1}(t)=\mathrm{erfc}\big(\theta/\sqrt{2p^l(t)}\big)/2$
(Eq. 1). Iteratively applying this relation results in the
activity converging either to $p^\infty(t)=0$ or to
$p^\infty(t)=p_s$, depending on whether $p^1(t) \geq p_u$ or
$p^1(t) \leq p_u$, respectively, with $p_s$ and $p_u$ as
shown in the figure. Since $p^1(t)$ is a monotonically
increasing function of time, this result means that, as the
activity propagates through layers, the timing of the state
change converges to the timing at which $p^1$ exceeds $p_u$.
Hence, the spikes become more synchronous and activate the
successive layer more reliably.We also show that, the
greater $P^1$ is, the earlier this converging timing
becomes, meaning that the network naturally converts the
activity level of the initial layer to the timing of the
spike pulse packet that propagates through the layers. We
demonstrate this in a network with multiple synfire chains
embedded and discuss the implications of this effect to
cortical information processing.},
month = {Sep},
date = {2024-09-29},
organization = {Bernstein Conference 2024, Frankfurt
(Germany), 29 Sep 2024 - 2 Oct 2024},
subtyp = {After Call},
cin = {IAS-6 / INM-10},
cid = {I:(DE-Juel1)IAS-6-20130828 / I:(DE-Juel1)INM-10-20170113},
pnm = {5231 - Neuroscientific Foundations (POF4-523) / HBP SGA2 -
Human Brain Project Specific Grant Agreement 2 (785907) /
HBP SGA3 - Human Brain Project Specific Grant Agreement 3
(945539) / HAF - Helmholtz Analytics Framework (ZT-I-0003) /
JL SMHB - Joint Lab Supercomputing and Modeling for the
Human Brain (JL SMHB-2021-2027) / Algorithms of Adaptive
Behavior and their Neuronal Implementation in Health and
Disease (iBehave-20220812) / GRK 2416 - GRK 2416:
MultiSenses-MultiScales: Neue Ansätze zur Aufklärung
neuronaler multisensorischer Integration (368482240)},
pid = {G:(DE-HGF)POF4-5231 / G:(EU-Grant)785907 /
G:(EU-Grant)945539 / G:(DE-HGF)ZT-I-0003 / G:(DE-Juel1)JL
SMHB-2021-2027 / G:(DE-Juel-1)iBehave-20220812 /
G:(GEPRIS)368482240},
typ = {PUB:(DE-HGF)6},
url = {https://juser.fz-juelich.de/record/1031974},
}
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