Efficient low temperature Monte Carlo sampling using quantum annealing
Roland Sandt, Robert Spatschek
Abstract
Quantum annealing is an efficient technology to determine ground state configurations of discrete binary optimization problems, described through Ising Hamiltonians. Here we show that-at very low computational cost-finite temperature properties can be calculated. The approach is most efficient at low temperatures, where conventional approaches like Metropolis Monte Carlo sampling suffer from high rejection rates and therefore large statistical noise. To demonstrate the general approach, we apply it to spin glasses and Ising chains.
Topics & Concepts
Quantum annealingIsing modelStatistical physicsMonte Carlo methodQuantum Monte CarloSimulated annealingMonte Carlo method in statistical physicsComputer scienceBinary numberSampling (signal processing)Ground stateQuantumMonte Carlo molecular modelingIsing spinHybrid Monte CarloQuantum computerAlgorithmPhysicsMarkov chain Monte CarloMathematicsQuantum mechanicsStatisticsArithmeticComputer visionFilter (signal processing)Theoretical and Computational PhysicsQuantum many-body systemsComplex Network Analysis Techniques