Tactile Network Resource Allocation enabled by Quantum Annealing based on ILP Modeling
Abstract
Agile networks with fast adaptation and reconfiguration capabilities are required for on-demand provisioning of various network services. We propose a new methodical framework for short-time network optimization based on quantum computing (QC) and integer linear program (ILP) models, which has the potential of realizing a real-time network automation. We define methods to map a nearly real-world ILP model for resource provisioning to a quadratic unconstrained binary optimization (QUBO) problem, which is solvable on quantum annealer (QA). We concentrate on the three-node network to evaluate our approach and its obtainable quality of solution using the state-of-the-art quantum annealer D-Wave Advantage 5.2/5.3. By studying the annealing process, we find annealing configuration parameters that obtain feasible solutions close to the reference solution generated by the classical ILP-solver CPLEX. Further, we studied the scaling of the network problem and provide estimations on quantum annealer's hardware requirements to enable a proper QUBO problem embedding of larger networks. We achieved the QUBO embedding of networks with up to 6 nodes on the D-Wave Advantage. According to our estimates a real-sized network with 12 to 16 nodes require a QA hardware with at least 50000 qubits or more.
Cite
@article{arxiv.2212.07854,
title = {Tactile Network Resource Allocation enabled by Quantum Annealing based on ILP Modeling},
author = {Arthur Witt and Christopher Körber and Andreas Kirstädter and Thomas Luu},
journal= {arXiv preprint arXiv:2212.07854},
year = {2023}
}
Comments
10 pages, 9 figures. Submitted to "IEEE Quantum Week 2023". The data of the work are available on https://jugit.fz-juelich.de/qnet-public/home/