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Computations that neurons perform in networks: lessons learned from a Sixteenth Century shoemaker

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Title Computations that neurons perform in networks: lessons learned from a Sixteenth Century shoemaker
Names Mpitsos, George J. (creator)
Edstrom, John P. (creator)
Date Issued 1998 (iso8601)
Abstract Cognitive
and
other
neural
processes
emerge
from
the
interactions
be-
tween
neurons.
Major
advances
have
been
made
in
studying
networks
in
which
the
interac-
fions
occur
instantaneously
by
means
ofgraded
synapses
(Guckenheimer
and
Rowat,
I
997).
In
other
networks,
the
interaction
between
neurons
involves
time-delayed
signals
(action
potentials
or
spikes)
that
activate
synapses
on
other
neurons
discontinuously
in
a
pulse-like
manner.
These
interactions
can
also
be
treated
as
being
graded
if,
when
appropriate,
the
information
transmitted
between
neurons
can
be
measured
as
the
average
number
of
spikes
per
unit
time
(Freeman,
1992);
i.e.,
the
amount
ofinformation
carried
by
individual
spikes
is
relatively
low.
We
refer
to
both
ofthese
types
ofinteractions
as
"graded."
There
is
a
large
armamentarium
of
mathematical
and
dynamical
systems
tools
for
studying
the
computa-
tions
that
such
neurons
perform.
There
is
also
a
complementary
connection
between
these
tools
and
biological
experimentation.
The
subject
of
the
present
paper
is
on
networks
in
which
averaging
can
not
be
done.
The
generation
of
spikes
in
these
neurons
is
significantly
affècted
by
the
temporal
order
of
spikes
sent
to
them
by
other
neurons.
Two
input
spike
trains,
having
the
saine
average
spikes
per
unit
time
but
different
temporal
spacing
between
the
spikes,
produce
different
outputs
in
target
neurons;
i.e.,
the
amount
of
information
carried
by
individual
spikes
is
relatively
high.
We
refer
to
these
networks
as
"spike-activated."
By
comparison
to
graded
networks,
there
is
little
formal
or
experimental
work
on
the
general
principles
underlying
these
networks.
There
are
many
nonlinear
physiological
processes
in
spike-activated
networks
that
need
to
be
considered.
We
have
begun
by
focusing
on
a
single
nonlinearity
analysis,
the
threshold
transition
between
spiking
and
nonspiking
behavior,
and
use
linear
perturbation
to
examine
it.
The
fmdings
indicate
that
there
may
be
an
epistemological
distinction
be-
tween
graded
networks
and
spike-activated
networks.
This
is
reminiscent
of
the
distinction
between
endophysics
and
exophysics
whose
resolutions
requires
an
external
observer
hav-
ing
information
about
a
system
and
its
external
universe
(Rössler,
1989).
Interestingly,
the
philosophical
roots
of
our
approach
and
the
study
of
dynamics
more
generally
may
be
traceable
to
Jacob
Böhme
(1575-1624),
a
mystic
and
contemporary
of
Descartes.
Böhme
influenced
many
philosophers
and
scientists,
and
may
have
provided
Isaac
Newton
the
metaphorical
insight
into
his
laws
of
physics
(Mpitsos,
1995;
Yates,
1972,
1979).
Genre Other
Topic Self-organizing systems. -- Engineering
Identifier Partial Proceedings of the First International Conference CASYS '97 on Computing Anticipatory Systems, Liege, Belgium, August 11-15, 1997, General Systems, Physical and Engineering Systems, Symposium ECHO II. Daniel M. Dubois (Ed.) v.2 p.327-340

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