A Max K-Cut Implementation for QAOA in the Measurement Based Quantum Computing Formalism

Sebastiano Corli; Daniele Dragoni; Massimiliano Proietti; Massimiliano Dispenza; Carlo Cavazzoni; Enrico Prati

A Max K-Cut Implementation for QAOA in the Measurement Based Quantum Computing Formalism

Sebastiano Corli, Daniele Dragoni, Massimiliano Proietti, Massimiliano Dispenza, Carlo Cavazzoni, Enrico Prati

Published: 01 Jan 2023, Last Modified: 09 May 2024QCE 2023EveryoneRevisionsBibTeXCC BY-SA 4.0

Abstract: The MaxCut is a combinatorial problem which belongs to the NP-hard class. The algorithm to solve it can be mapped into a quantum system, where the optimal configuration matches the ground state of a target Hamiltonian. It is possible to implement the adiabatic theorem into the circuit model via the QAOA algorithm, by arbitrarily choosing from both the gate-based and the measurement-based quantum computing (MBQC) settings. Recently, the MaxCut problem has been generalized to the Max K-Cut version also in the MBQC frame, where K stands for the number of cuts to implement. Here, the QAOA algorithm for a Max K-Cut is solved for a graph with arbitrary number of vertices V and number of cuts K scaling as a power of 2, along with the circuit depth p. The problem is solved on a emulator based on classical HPC resources. In order to test the performances of a Max K-cut implemented in the MBQC frame, we report how the average runtime and the approximation ratio scale by increasing V, K and p, comparing the results from two different topologies of graphs, 2-regular graphs with null weights on the diagonals versus the the fully-connected graphs. Eventually, the approximation ratio, evaluated as a parameter of success, is shown to yield optimal performances.

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