21 research outputs found
Complexity of Road Coloring with Prescribed Reset Words
By the Road Coloring Theorem (Trahtman, 2008), the edges of any aperiodic
directed multigraph with a constant out-degree can be colored such that the
resulting automaton admits a reset word. There may also be a need for a
particular reset word to be admitted. For certain words it is NP-complete to
decide whether there is a suitable coloring of a given multigraph. We present a
classification of all words over the binary alphabet that separates such words
from those that make the problem solvable in polynomial time. We show that the
classification becomes different if we consider only strongly connected
multigraphs. In this restricted setting the classification remains incomplete.Comment: To be presented at LATA 201
On the Number of Synchronizing Colorings of Digraphs
We deal with -out-regular directed multigraphs with loops (called simply
\emph{digraphs}). The edges of such a digraph can be colored by elements of
some fixed -element set in such a way that outgoing edges of every vertex
have different colors. Such a coloring corresponds naturally to an automaton.
The road coloring theorem states that every primitive digraph has a
synchronizing coloring.
In the present paper we study how many synchronizing colorings can exist for
a digraph with vertices. We performed an extensive experimental
investigation of digraphs with small number of vertices. This was done by using
our dedicated algorithm exhaustively enumerating all small digraphs. We also
present a series of digraphs whose fraction of synchronizing colorings is equal
to , for every and the number of vertices large enough.
On the basis of our results we state several conjectures and open problems.
In particular, we conjecture that is the smallest possible fraction of
synchronizing colorings, except for a single exceptional example on 6 vertices
for .Comment: CIAA 2015. The final publication is available at
http://link.springer.com/chapter/10.1007/978-3-319-22360-5_1
Parameterized Complexity of Synchronization and Road Coloring
First, we close the multivariate analysis of a canonical problem concerning
short reset words (SYN), as it was started by Fernau et al. (2013). Namely, we
prove that the problem, parameterized by the number of states, does not admit a
polynomial kernel unless the polynomial hierarchy collapses. Second, we
consider a related canonical problem concerning synchronizing road colorings
(SRCP). Here we give a similar complete multivariate analysis. Namely, we show
that the problem, parameterized by the number of states, admits a polynomial
kernel and we close the previous research of restrictions to particular values
of both the alphabet size and the maximum word length