English

Generalized Counting Constraint Satisfaction Problems With Determinantal Circuits

Category Theory 2015-10-08 v3 Combinatorics

Abstract

Generalized counting constraint satisfaction problems include Holant problems with planarity restrictions; polynomial-time algorithms for such problems include matchgates and matchcircuits, which are based on Pfaffians. In particular, they use gates which are expressible in terms of a vector of sub-Pfaffians of a skew-symmetric matrix. We introduce a new type of circuit based instead on determinants, with seemingly different expressive power. In these determinantal circuits, a gate is represented by the vector of all minors of an arbitrary matrix. Determinantal circuits permit a different class of gates. Applications of these circuits include proofs of theorems from algebraic graph theory including the Chung-Langlands formula for the number of rooted spanning forests of a graph and computing Tutte Polynomials of certain matroids. They also give a strategy for simulating quantum circuits with closed timelike curves. Monoidal category theory provides a useful language for discussing such counting problems, turning combinatorial restrictions into categorical properties. We introduce the counting problem in monoidal categories and count-preserving functors as a way to study FP subclasses of problems in settings which are generally #P-hard. Using this machinery we show that, surprisingly, determinantal circuits can be simulated by Pfaffian circuits at quadratic cost.

Keywords

Cite

@article{arxiv.1302.1932,
  title  = {Generalized Counting Constraint Satisfaction Problems With Determinantal Circuits},
  author = {Jason Morton and Jacob Turner},
  journal= {arXiv preprint arXiv:1302.1932},
  year   = {2015}
}
R2 v1 2026-06-21T23:22:58.622Z