The Quantum Walk Characteristic Polynomial Distinguishes All Strongly Regular Graphs of Prime Orde

Abstract

Let G be a strongly regular graph of prime order p with connection degree k ≥ 6. We prove that the quantum walk characteristic polynomial q(G,λ) (λ I - UG), where UG is the coined quantum walk operator on G, completely determines G up to isomorphism within the class of strongly regular graphs of the same order. The proof proceeds in three steps. First, we show that UG block-diagonalizes under the discrete Fourier transform over p, yielding p blocks UG(j) of size k × k. Second, we prove an explicit formula \[ q\!(UG(j), λ) = (λ-1)(k-2)/2(λ+1)(k-2)/2 \!(λ2 - 2AG(j)k\,λ + 1), \] from which the Fourier coefficient AG(j) is recovered as the unique real part of an eigenvalue of UG(j) distinct from 1. Third, the inverse discrete Fourier transform recovers the connection set S of G, and Turner's theorem (1967) identifies G up to isomorphism. As a consequence, graph isomorphism is decidable in polynomial time within this class using the quantum walk spectrum, without resorting to the general quasi-polynomial algorithm of Babai (2016).