Quantum mechanics is expected to revolutionize the computing landscape in the near future. Among the many candidate technologies for building universal quantum computers, Rydberg atoms-based systems stand out for being capable of performing both quantum simulations and working as gate-based universal quantum computers while operating at room temperature through an optical system. Moreover, they can potentially scale up to hundreds of quantum bits (qubits). In this work, we solve a Graph Coloring problem by iteratively computing the solutions of Maximal Independent Set (MIS) problems, exploiting the Rydberg blockade phenomenon. Experimental results using a simulation framework on the CINECA Marconi-100 supercomputer demonstrate the validity of the proposed approach.
Towards Optimal Graph Coloring Using Rydberg Atoms / Vitali, Giacomo; Viviani, Paolo; Vercellino, Chiara; Scionti, Alberto; Scarabosio, Andrea; Terzo, Olivier; Giusto, Edoardo; Montrucchio, Bartolomeo. - (2021). (Intervento presentato al convegno Supercomputing 2021 (SC21) tenutosi a St. Louis, MO (USA) nel November 14–19 2021).
Towards Optimal Graph Coloring Using Rydberg Atoms
Edoardo Giusto;
2021
Abstract
Quantum mechanics is expected to revolutionize the computing landscape in the near future. Among the many candidate technologies for building universal quantum computers, Rydberg atoms-based systems stand out for being capable of performing both quantum simulations and working as gate-based universal quantum computers while operating at room temperature through an optical system. Moreover, they can potentially scale up to hundreds of quantum bits (qubits). In this work, we solve a Graph Coloring problem by iteratively computing the solutions of Maximal Independent Set (MIS) problems, exploiting the Rydberg blockade phenomenon. Experimental results using a simulation framework on the CINECA Marconi-100 supercomputer demonstrate the validity of the proposed approach.| File | Dimensione | Formato | |
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