Showing total 2 results

1. EDGE-DISJOINT PATHS IN PLANAR GRAPHS WITH CONSTANT CONGESTION.

Author

CHEKURI, CHANDRA, KHANNA, SANJEEV, and SHEPHERD, F. BRUCE

Subjects

GRAPH theory, GRAPHIC methods, COMBINATORICS, ALGEBRA, MATHEMATICAL analysis, ALGORITHMS, EMBEDDINGS (Mathematics), ALGEBRAIC geometry, MATHEMATICS

Abstract

We study the maximum edge-disjoint paths problem in undirected planar graphs: given a graph G and node pairs (demands) s1t1, s2t2, … , sktk, the goal is to maximize the number of demands that can be connected (routed) by edge-disjoint paths. The natural multicommodity flow relaxation has an Ω(√n) integrality gap, where n is the number of nodes in G. Motivated by this, we consider solutions with small constant congestion c > 1, that is, solutions in which up to c paths are allowed to use an edge (alternatively, each edge has a capacity of c). In previous work we obtained an O(log n) approximation with congestion 2 via the flow relaxation. This was based on a method of decomposing into well-linked subproblems. In this paper we obtain an O(1) approximation with congestion 4. To obtain this improvement we develop an alternative decomposition that is specific to planar graphs. The decomposition produces instances that we call Okamura-Seymour (OS) instances. These have the property that all terminals lie on a single face. Another ingredient we develop is a constant factor approximation for the all-or-nothing flow problem on OS instances via the flow relaxation. [ABSTRACT FROM AUTHOR]

Published

2009

2. Decycling Cartesian Products of Two Cycles.

Author

Pike, David A. and Yubo Zou

Subjects

*MATHEMATICS, *GRAPH theory, *CLOSED graph theorems, *MATHEMATICAL analysis, *LINEAR programming, *ALGORITHMS

Abstract

The decycling number $\nabla(G)$ of a graph $G$ is the smallest number of vertices which can be removed from $G$ so that the resultant graph contains no cycles. In this paper, we study the decycling number for the family of graphs consisting of the Cartesian product of two cycles. We completely solve the problem of determining the decycling number of $C_m \square C_n$ for all $m$ and $n$. Moreover, we find a vertex set $T$ that yields a maximum induced tree in $C_m\square C_n$. [ABSTRACT FROM AUTHOR]

Published

2005