On the Complexity of the Circuit Width Problem

Abstract

Montanaro's polynomial representation expresses amplitudes of quantum circuits over the gates H, Z, CZ, and CCZ as normalized gaps of degree-three polynomials over F2. The normalization is governed by the circuit width w(f), the minimum number of qubits in any circuit realizing a polynomial f. Thus, efficient width minimization would give an approximate-counting route toward a combinatorial characterization of BQP. We study the computational complexity of this parameter. For degree-three polynomials with no constant term, deciding whether w(f) k is NP-complete, resolving Montanaro's open question. We also prove NP-hardness of approximation within any factor 49/48-ε, and show via a twin-copy construction that the exact and approximation hardness results also hold for degree-two polynomials. Under the Exponential Time Hypothesis, the exact problem admits no 2o(n)-time algorithm when k=Θ(n). Complementing these hardness results, we give a nondeterministic polynomial-time search algorithm using 22nk=O(k(en/k)) witness bits, and a constructive fixed-parameter algorithm parameterized by k with running time k6k+o(k)n+O(m).