Paper Info
Title
The counting complexity of group-definable languages
Abstract
A group family is a countable family B ={B n } n>0 of finite black-box groups , i.e., the elements of each group B n are uniquely encoded as strings of uniform length (polynomial in n ) and for each B n the group operations are computable in time polynomial in n . In this paper we study the complexity of NP sets A which has the following property: the set of solutions for every x ∈ A is a subgroup (or is the right coset of a subgroup) of a group B i (| x |) from a given group family B , where i is a polynomial. Such an NP set A is said to be defined over the group family B . Decision problems like Graph Automorphism, Graph Isomorphism, Group Intersection, Coset Intersection, and Group Factorization for permutation groups give natural examples of such NP sets defined over the group family of all permutation groups. We show that any such NP set defined over permutation groups is low for PP and C = P. As one of our main results we prove that NP sets defined over abelian black-box groups are low for PP. The proof of this result is based on the decomposition theorem for finite abelian groups. As an interesting consequence of this result we obtain new lowness results: Membership Testing, Group Intersection, Group Factorization, and some other problems for abelian black-box groups are low for PP and C = P. As regards the corresponding counting problem for NP sets over any group family of arbitrary black-box groups, we prove that exact counting of number of solutions is in FP AM . Consequently, none of these counting problems can be #P-complete unless PH collapses.
Year
DOI
Venue
2000
10.1016/S0304-3975(98)00218-7
Theor. Comput. Sci.
Keywords
DocType
Volume
group-definable language,NP-complete,Group definable languages,Group Family
Journal
242
Issue
ISSN
Citations 
1-2
Theoretical Computer Science
2
PageRank 
References 
Authors
0.38
13
2
Name
Order
Citations
PageRank
V. Arvind112212.03
N. V. Vinodchandran229430.56