English

Quantum computing algorithms for inverse problems on graphs and an NP-complete inverse problem

Combinatorics 2024-02-13 v2 Computational Complexity Quantum Physics

Abstract

We consider an inverse problem for a finite graph (X,E)(X,E) where we are given a subset of vertices BXB\subset X and the distances d(X,E)(b1,b2)d_{(X,E)}(b_1,b_2) of all vertices b1,b2Bb_1,b_2\in B. The distance of points x1,x2Xx_1,x_2\in X is defined as the minimal number of edges needed to connect two vertices, so all edges have length 1. The inverse problem is a discrete version of the boundary rigidity problem in Riemannian geometry or the inverse travel time problem in geophysics. We will show that this problem has unique solution under certain conditions and develop quantum computing methods to solve it. We prove the following uniqueness result: when (X,E)(X,E) is a tree and BB is the set of leaves of the tree, the graph (X,E)(X,E) can be uniquely determined in the class of all graphs having a fixed number of vertices. We present a quantum computing algorithm which produces a graph (X,E)(X,E), or one of those, which has a given number of vertices and the required distances between vertices in BB. To this end we develop an algorithm that takes in a qubit representation of a graph and combine it with Grover's search algorithm. The algorithm can be implemented using only O(X2)O(|X|^2) qubits, the same order as the number of elements in the adjacency matrix of (X,E)(X,E). It also has a quadratic improvement in computational cost compared to standard classical algorithms. Finally, we consider applications in theory of computation, and show that a slight modification of the above inverse problem is NP-complete: all NP-problems can be reduced to a discrete inverse problem we consider.

Keywords

Cite

@article{arxiv.2306.05253,
  title  = {Quantum computing algorithms for inverse problems on graphs and an NP-complete inverse problem},
  author = {Joonas Ilmavirta and Matti Lassas and Jinpeng Lu and Lauri Oksanen and Lauri Ylinen},
  journal= {arXiv preprint arXiv:2306.05253},
  year   = {2024}
}

Comments

42 pages, 3 figures; added numerical examples (appendix A)

R2 v1 2026-06-28T11:00:05.510Z