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An Ensemble Approach for Compressive Sensing with Quantum Annealers

Ramin Ayanzadeh, Milton Halem, Tim Finin

202019 citationsDOI

Abstract

We leverage the idea of a statistical ensemble to improve the quality of quantum annealing based binary compressive sensing. Since executing quantum machine instructions on a quantum annealer can result in an excited state, rather than the ground state of the given Hamiltonian, we use different penalty parameters to generate multiple distinct quadratic unconstrained binary optimization (QUBO) functions whose ground state(s) represent a potential solution of the original problem. We then employ the attained samples from minimizing all corresponding (different) QUBOs to estimate the solution of the problem of binary compressive sensing. Our experiments, on a D-Wave 2000Q quantum processor, demonstrated that the proposed ensemble scheme is notably less sensitive to the calibration of the penalty parameter that controls the trade-off between the feasibility and sparsity of recoveries.

Topics & Concepts

Quadratic unconstrained binary optimizationQuantum annealingCompressed sensingQuantumBinary numberLeverage (statistics)Computer scienceGround stateAlgorithmSimulated annealingHamiltonian (control theory)Quadratic equationStatistical ensembleQuantum computerMathematical optimizationArtificial intelligencePhysicsMathematicsQuantum mechanicsCanonical ensembleGeometryStatisticsArithmeticMonte Carlo methodSparse and Compressive Sensing TechniquesQuantum Computing Algorithms and ArchitectureBlind Source Separation Techniques
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