This is the first of two chapters of a work in which we consider the unrestricted, minimal, and bounded representation problems for unit interval (UIG) and unit circular-arc (UCA) graphs. In the unrestricted version, a proper circular-arc (PCA) model M is given and the goal is to obtain an equivalent UCA model U . In the bounded version, M is given together with some lower and upper bounds that the beginning points of U must satisfy. In the minimal version, we have to find a minimal model equivalent to M , in which the circumference of the circle and length of the arcs must be simultaneously as small as possible. In this chapter we motivate these problems from an historical perspective, and we develop the theoretical framework required for ...
A circular-arc model M is a circle C together with a collection A of arcs of C. If A satisfies the H...
We present a logspace algorithm that constructs a canonical intersection model for a given proper ci...
Let A be a set of n arcs on the unit circle. We present a new simple 2(n log n)-time algorithm for c...
This is the second and last chapter of a work in which we consider the unrestricted, minimal, and bo...
We consider the unrestricted, minimal, and bounded representation problems for unit interval (UIG) a...
In a recent paper, Durán, Gravano, McConnell, Spinrad and Tucker described an algorithm of complexi...
In a recent paper, Durán, Gravano, McConnell, Spinrad and Tucker described an algorithm of complexi...
AbstractWe investigate some properties of minimal interval and circular arc representations and give...
We present an efficient algorithm for recognizing unit circular-arc (UCA) graphs, based on a charact...
AbstractA proper circular-arc graph is a graph that has an intersection model formed by a family of ...
We present a dynamic algorithm for the recognition of proper circular-arc (PCA) graphs, that support...
In 1969, Tucker characterized proper circular-arc graphs as those graphs whose augmented adjacency m...
A Helly circular-arc model M=(C,A) is a circle C together with a Helly family A of arcs of C. If no ...
We present a fully dynamic algorithm for the recognition of proper circular-arc (PCA) graphs. The al...
A Helly circular-arc modelM = (C,A) is a circle C together with a Helly family A of arcs of C. If no...
A circular-arc model M is a circle C together with a collection A of arcs of C. If A satisfies the H...
We present a logspace algorithm that constructs a canonical intersection model for a given proper ci...
Let A be a set of n arcs on the unit circle. We present a new simple 2(n log n)-time algorithm for c...
This is the second and last chapter of a work in which we consider the unrestricted, minimal, and bo...
We consider the unrestricted, minimal, and bounded representation problems for unit interval (UIG) a...
In a recent paper, Durán, Gravano, McConnell, Spinrad and Tucker described an algorithm of complexi...
In a recent paper, Durán, Gravano, McConnell, Spinrad and Tucker described an algorithm of complexi...
AbstractWe investigate some properties of minimal interval and circular arc representations and give...
We present an efficient algorithm for recognizing unit circular-arc (UCA) graphs, based on a charact...
AbstractA proper circular-arc graph is a graph that has an intersection model formed by a family of ...
We present a dynamic algorithm for the recognition of proper circular-arc (PCA) graphs, that support...
In 1969, Tucker characterized proper circular-arc graphs as those graphs whose augmented adjacency m...
A Helly circular-arc model M=(C,A) is a circle C together with a Helly family A of arcs of C. If no ...
We present a fully dynamic algorithm for the recognition of proper circular-arc (PCA) graphs. The al...
A Helly circular-arc modelM = (C,A) is a circle C together with a Helly family A of arcs of C. If no...
A circular-arc model M is a circle C together with a collection A of arcs of C. If A satisfies the H...
We present a logspace algorithm that constructs a canonical intersection model for a given proper ci...
Let A be a set of n arcs on the unit circle. We present a new simple 2(n log n)-time algorithm for c...