AbstractGiven a positive even integer n, we show how to generate the set G(n) of graphical partitions of n, that is, those partitions of n which correspond to the degree sequences of simple, undirected graphs. The algorithm is based on a recurrence for G(n), and the total time used by the algorithm, independent of output, is O(¦G(n)¦), which is constant average time per graphical partition. This is the first algorithm shown to achieve such efficiency for generating G(n) and the direct approach differs from earlier ‘generate and reject’ schemes and the ‘interval/gap’ approach
We present an algorithm to test whether a given graphical degree sequence is forcibly biconnected. T...
Given a graph G, we intend to partition its nodes into two sets of equal size so as to minimize the ...
We consider the problem of recovering a planted partition (e.g., a small bisection or a large cut) f...
Given a positive even integer n, we show how to generate the set G(n) of graphical partitions of n,...
In this paper, we give a recurrence to enumerate the set G(n) of partitions of a positive even inte...
Several algorithms for generating partitions of positive numbers are given. First, an algorithm for...
A partition of an integer n is graphical if it is the degree sequence of a simple undirected graph ...
AbstractWe give a simple proof that the number of graphical partitions of an even positive integer n...
We present an algorithm to test whether a given graphical degree sequence is forcibly connected or n...
The present paper greatly extends and elaborates the results of a previous paper by Stein on the enu...
In this thesis we consider the problem of generating integer partitions. We provide an overview of a...
The degree partition of a simple graph is its degree sequence rearranged in weakly decreasing order....
Graph partitioning is the problem of splitting a graph into two or more partitions of fixed sizes wh...
International audienceWe address here the problem of generating random graphs uniformly from the set...
A sequence d = (d1, d2, …, dn) of integers is a degree sequence if there exists a (simple) graph G s...
We present an algorithm to test whether a given graphical degree sequence is forcibly biconnected. T...
Given a graph G, we intend to partition its nodes into two sets of equal size so as to minimize the ...
We consider the problem of recovering a planted partition (e.g., a small bisection or a large cut) f...
Given a positive even integer n, we show how to generate the set G(n) of graphical partitions of n,...
In this paper, we give a recurrence to enumerate the set G(n) of partitions of a positive even inte...
Several algorithms for generating partitions of positive numbers are given. First, an algorithm for...
A partition of an integer n is graphical if it is the degree sequence of a simple undirected graph ...
AbstractWe give a simple proof that the number of graphical partitions of an even positive integer n...
We present an algorithm to test whether a given graphical degree sequence is forcibly connected or n...
The present paper greatly extends and elaborates the results of a previous paper by Stein on the enu...
In this thesis we consider the problem of generating integer partitions. We provide an overview of a...
The degree partition of a simple graph is its degree sequence rearranged in weakly decreasing order....
Graph partitioning is the problem of splitting a graph into two or more partitions of fixed sizes wh...
International audienceWe address here the problem of generating random graphs uniformly from the set...
A sequence d = (d1, d2, …, dn) of integers is a degree sequence if there exists a (simple) graph G s...
We present an algorithm to test whether a given graphical degree sequence is forcibly biconnected. T...
Given a graph G, we intend to partition its nodes into two sets of equal size so as to minimize the ...
We consider the problem of recovering a planted partition (e.g., a small bisection or a large cut) f...