3,599 research outputs found
Intrinsically Universal Cellular Automata
This talk advocates intrinsic universality as a notion to identify simple
cellular automata with complex computational behavior. After an historical
introduction and proper definitions of intrinsic universality, which is
discussed with respect to Turing and circuit universality, we discuss
construction methods for small intrinsically universal cellular automata before
discussing techniques for proving non universality
Majority-Vote Cellular Automata, Ising Dynamics, and P-Completeness
We study cellular automata where the state at each site is decided by a
majority vote of the sites in its neighborhood. These are equivalent, for a
restricted set of initial conditions, to non-zero probability transitions in
single spin-flip dynamics of the Ising model at zero temperature.
We show that in three or more dimensions these systems can simulate Boolean
circuits of AND and OR gates, and are therefore P-complete. That is, predicting
their state t time-steps in the future is at least as hard as any other problem
that takes polynomial time on a serial computer.
Therefore, unless a widely believed conjecture in computer science is false,
it is impossible even with parallel computation to predict majority-vote
cellular automata, or zero-temperature single spin-flip Ising dynamics,
qualitatively faster than by explicit simulation.Comment: 10 pages with figure
Dichotomy Results for Fixed-Point Existence Problems for Boolean Dynamical Systems
A complete classification of the computational complexity of the fixed-point
existence problem for boolean dynamical systems, i.e., finite discrete
dynamical systems over the domain {0, 1}, is presented. For function classes F
and graph classes G, an (F, G)-system is a boolean dynamical system such that
all local transition functions lie in F and the underlying graph lies in G. Let
F be a class of boolean functions which is closed under composition and let G
be a class of graphs which is closed under taking minors. The following
dichotomy theorems are shown: (1) If F contains the self-dual functions and G
contains the planar graphs then the fixed-point existence problem for (F,
G)-systems with local transition function given by truth-tables is NP-complete;
otherwise, it is decidable in polynomial time. (2) If F contains the self-dual
functions and G contains the graphs having vertex covers of size one then the
fixed-point existence problem for (F, G)-systems with local transition function
given by formulas or circuits is NP-complete; otherwise, it is decidable in
polynomial time.Comment: 17 pages; this version corrects an error/typo in the 2008/01/24
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Complexity, parallel computation and statistical physics
The intuition that a long history is required for the emergence of complexity
in natural systems is formalized using the notion of depth. The depth of a
system is defined in terms of the number of parallel computational steps needed
to simulate it. Depth provides an objective, irreducible measure of history
applicable to systems of the kind studied in statistical physics. It is argued
that physical complexity cannot occur in the absence of substantial depth and
that depth is a useful proxy for physical complexity. The ideas are illustrated
for a variety of systems in statistical physics.Comment: 21 pages, 7 figure
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