Berlin 2012 – wissenschaftliches Programm

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DY: Fachverband Dynamik und Statistische Physik

DY 31: Phase Transitions and Critical Phenomena

DY 31.10: Vortrag

Freitag, 30. März 2012, 12:15–12:30, MA 004

Improved Linear Programming applied to the Vertex Cover Problem — •Timo Dewenter and Alexander K. Hartmann — Institut für Physik, Universität Oldenburg, 26111 Oldenburg

We consider the well studied [1] NP-complete Vertex Cover problem (VC) on Erdős-Rényi (ER) random graphs with finite connectivity c.

Previously, we applied the mapping of VC to a Linear Programming problem (LP), where the nodes of the graph are represented by real-valued variables x_i ∈ [0,1]. A value of x_i = 0 means that the node is uncovered and x_i = 1 denotes a covered node. Each edge {j,k} in the graph is related to a constraint x_j + x_k ≥ 1 in the LP. The Simplex-algorithm is then applied to solve this LP, but for larger c incomplete solutions with variables x_i ∈ ]0,1[ are found. So we used a cutting-plane approach that adds constraints to the LP based on loops in the graph with odd length leading typically to exact solutions for c < e ≈ 2.718.

Here, we solve small subgraphs G_S =(U,E_U) with an exact algorithm and add contraints ∑_{xi ∈ U} ≥ |V_C(G_S)| to the LP, where |V_C(G_S)| is the size of the minimum VC of G_S. This leads in principle to complete solutions, but here we only use |U| ≤ 10. The behaviour of this algorithm is studied for ER random graphs as a function of c. After performing statistical analyses [2] for different system sizes, we compare with the phase diagram for the critical fraction x_c of covered vertices.
M. Weigt and A.K. Hartmann, Phys. Rev. Lett. 84, 26 (2000)
A.K. Hartmann: Practical Guide to Computer Simulations, World-Scientific, 2009