AbstractA simple decomposition for graphs yields generating functions for counting graphs by edges and connected components. A change of variables gives a new interpretation to the Tutte polynomial of the complete graph involving inversions of trees. The relation between the Tutte polynomial of the complete graph and the inversion enumerator for trees is generalized to the Tutte polynomial of an arbitrary graph. When applied to digraphs, the decomposition yields formulas for counting digraphs and acyclic digraphs by edges and initially connected components
Given any graph G, there is a bivariate polynomial called Tutte polynomial which can be derived from...
AbstractWe give a combinatorial interpretation of the evaluation at (3, 3) of the Tutte polynomial o...
In this paper, using a well-known recursion for computing the Tutte polynomial of any graph, we foun...
AbstractA simple decomposition for graphs yields generating functions for counting graphs by edges a...
AbstractA depth first search algorithm is used to establish the connection between labeled connected...
AbstractThe V-functions of Tutte [1] are generalized to U-functions on graphs with a distinguished s...
AbstractThis paper describes how I became acquainted with the Tutte polynomial, and how I was led to...
Graph polynomials are polynomials associated to graphs that encode the number of subgraphs with give...
AbstractInspired by the study of community structure in connection networks, we introduce the graph ...
We prove some variants of the exponential formula and apply them to the multivariate Tutte polynomia...
AbstractThe analysis of many algorithms concerning trees requires the enumeration of families of nod...
We give a new characterization of the Tutte polynomial of graphs. Our characterization is formally c...
AbstractKreweras studied a polynomialPn(q) which enumerates (labeled) rooted forests by number of in...
AbstractThe line-digraph of a digraph D with vertices V1, …, Vn is the digraph D∗ obtained from D by...
We define a new graph polynomial, the interlace polynomial, for any undirected graph. Also, we show ...
Given any graph G, there is a bivariate polynomial called Tutte polynomial which can be derived from...
AbstractWe give a combinatorial interpretation of the evaluation at (3, 3) of the Tutte polynomial o...
In this paper, using a well-known recursion for computing the Tutte polynomial of any graph, we foun...
AbstractA simple decomposition for graphs yields generating functions for counting graphs by edges a...
AbstractA depth first search algorithm is used to establish the connection between labeled connected...
AbstractThe V-functions of Tutte [1] are generalized to U-functions on graphs with a distinguished s...
AbstractThis paper describes how I became acquainted with the Tutte polynomial, and how I was led to...
Graph polynomials are polynomials associated to graphs that encode the number of subgraphs with give...
AbstractInspired by the study of community structure in connection networks, we introduce the graph ...
We prove some variants of the exponential formula and apply them to the multivariate Tutte polynomia...
AbstractThe analysis of many algorithms concerning trees requires the enumeration of families of nod...
We give a new characterization of the Tutte polynomial of graphs. Our characterization is formally c...
AbstractKreweras studied a polynomialPn(q) which enumerates (labeled) rooted forests by number of in...
AbstractThe line-digraph of a digraph D with vertices V1, …, Vn is the digraph D∗ obtained from D by...
We define a new graph polynomial, the interlace polynomial, for any undirected graph. Also, we show ...
Given any graph G, there is a bivariate polynomial called Tutte polynomial which can be derived from...
AbstractWe give a combinatorial interpretation of the evaluation at (3, 3) of the Tutte polynomial o...
In this paper, using a well-known recursion for computing the Tutte polynomial of any graph, we foun...