Daniel W. Cranston, Moritz Mühlenthaler, Benjamin Peyrille
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A simple quadratic kernel for Token Jumping on surfaces
The problem \textsc{Token Jumping} asks whether, given a graph $G$ and two
independent sets of \emph{tokens} $I$ and $J$ of $G$, we can transform $I$ into
$J$ by changing the position of a single token in each step and having an
independent set of tokens throughout. We show that there is a polynomial-time
algorithm that, given an instance of \textsc{Token Jumping}, computes an
equivalent instance of size $O(g^2 + gk + k^2)$, where $g$ is the genus of the
input graph and $k$ is the size of the independent sets.
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