Consider a complete communication network of $n$ nodes, where the nodes
receive a common clock pulse. We study the synchronous $c$-counting problem:
given any starting state and up to $f$ faulty nodes with arbitrary behaviour,
the task is to eventually have all correct nodes counting modulo $c$ in
agreement. Thus, we are considering algorithms that are self-stabilizing
despite Byzantine failures. In this work, we give new algorithms for the
synchronous counting problem that (1) are deterministic, (2) have linear
stabilisation time in $f$, (3) use a small number of states, and (4) achieve
almost-optimal resilience. Prior algorithms either resort to randomisation, use
a large number of states, or have poor resilience. In particular, we achieve an
exponential improvement in the space complexity of deterministic algorithms,
while still achieving linear stabilisation time and almost-linear resilience.Comment: 17 pages, 2 figure

Lenzen, Christoph

Rybicki, Joel

Suomela, Jukka

English

arXiv

Consider a complete communication network of n nodes, in which the nodes receive a common clock pulse. We study the synchronous c-counting problem: given any starting state and up to f faulty nodes with arbitrary behaviour, the task is to eventually have all correct nodes count mod-ulo c in agreement. Thus, we are considering algorithms that are self-stabilising despite Byzantine failures. In this work, we give new algorithms for the synchronous counting problem that (1) are deterministic, (2) have linear stabil-isation time in f, (3) use a small number of states, and (4) achieve almost-optimal resilience. Prior algorithms either resort to randomisation, use a large number of states, or have poor resilience. In particular, we achieve an exponen-tial improvement in the state complexity of deterministic algorithms, while still achieving linear stabilisation time and almost-linear resilience

Christoph Lenzen

Joel Rybicki

Jukka Suomela

CiteSeerX

Towards optimal synchronous counting

Lenzen, C.

Rybicki, J.

Suomela, J.

MPG.PuRe

Towards Optimal Synchronous Counting

Consider a complete communication network of $n$ nodes, where the nodes receive a common clock pulse. We study the synchronous $c$-counting problem: given any starting state and up to $f$ faulty nodes with arbitrary behaviour, the task is to eventually have all correct nodes counting modulo $c$ in agreement. Thus, we are considering algorithms that are self-stabilizing despite Byzantine failures. In this work, we give new algorithms for the synchronous counting problem that (1) are deterministic, (2) have linear stabilisation time in $f$, (3) use a small number of states, and (4) achieve almost-optimal resilience. Prior algorithms either resort to randomisation, use a large number of states, or have poor resilience. In particular, we achieve an exponential improvement in the space complexity of deterministic algorithms, while still achieving linear stabilisation time and almost-linear resilience

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http://people.mpi-inf.mpg.de/%7Eclenzen/pubs/LRS15counting.pdf

Towards Optimal Synchronous Counting

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