A quantum unstructured search algorithm for discrete optimisation: the use case of portfolio optimisation
Abstract
We propose a quantum unstructured search algorithm to find the extrema or roots of discrete functions, , such as the objective functions in combinatorial and other discrete optimisation problems. The first step of the Quantum Search for Extrema and Roots Algorithm (QSERA) is to translate conditions of the form , where is the extremum or zero, to an unstructured search problem for . This is achieved by mapping to a function to create a quantum oracle, such that and . The next step is to employ Grover's algorithm to find , which offers a quadratic speed-up over classical algorithms. The number of operations needed to map to determines the accuracy of the result and the circuit depth. We describe the implementation of QSERA by assembling a quantum circuit for portfolio optimisation, which can be formulated as a combinatorial problem. QSERA can handle objective functions with higher order terms than the commonly-used Quadratic Unconstrained Binary Optimisation (QUBO) framework. Moreover, while QSERA requires some a priori knowledge of the extrema of , it can still find approximate solutions even if the conditions are not exactly satisfied.
Cite
@article{arxiv.2505.14645,
title = {A quantum unstructured search algorithm for discrete optimisation: the use case of portfolio optimisation},
author = {Titos Matsakos and Adrian Lomas},
journal= {arXiv preprint arXiv:2505.14645},
year = {2026}
}
Comments
21 pages