The complexity of approximating PSPACE-Complete problems for hierarchical specifications

Abstract

We extend the concept of polynomial time approximation algorithms to apply to problems for hierarchically specified graphs, many of which are PSPACE-complete. Assuming P != PSPACE, the existence or nonexistence of such efficient approximation algorithms is characterized, for several standard graph theoretic and combinatorial problems. We present polynomial time approximation algorithms for several standard PSPACE-hard problems considered in the literature. In contrast, we show that unless P = PSPACE, there is no polynomial time epsilon-approximation for any epsilon>0, for several other problems, when the instances are specified hierarchically. We present polynomial time approximation algorithms for the following problems when the graphs are specified hierarchically: minimum vertex cover, maximum 3SAT, weighted max cut, minimum maximal matching, bounded degree maximum independent set In contrast, we show that unless P = PSPACE, there is no polynomial time epsilon-approximation for any epsilon>0, for the following problems when the instances are specified hierarchically: the number of true gates in a monotone acyclic circuit when all input values are specified and the optimal value of the objective function of a linear program It is also shown that unless P = PSPACE, a performance guarantee of less than 2 cannot be obtained in polynomial time for the following problems when the instances are specified hierarchically: high degree subgraph, k-vertex connected subgraph, and k-edge connected subgraph

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