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Variational quantum Boltzmann machines

Christa Zoufal, Aurélien Lucchi, Stefan Woerner

2021Quantum Machine Intelligence97 citationsDOIOpen Access PDF

Abstract

Abstract This work presents a novel realization approach to quantum Boltzmann machines (QBMs). The preparation of the required Gibbs states, as well as the evaluation of the loss function’s analytic gradient, is based on variational quantum imaginary time evolution, a technique that is typically used for ground-state computation. In contrast to existing methods, this implementation facilitates near-term compatible QBM training with gradients of the actual loss function for arbitrary parameterized Hamiltonians which do not necessarily have to be fully visible but may also include hidden units. The variational Gibbs state approximation is demonstrated with numerical simulations and experiments run on real quantum hardware provided by IBM Quantum. Furthermore, we illustrate the application of this variational QBM approach to generative and discriminative learning tasks using numerical simulation.

Topics & Concepts

Boltzmann constantQuantumBoltzmann machineStatistical physicsPhysicsComputer scienceTheoretical physicsQuantum mechanicsArtificial intelligenceArtificial neural networkGenerative Adversarial Networks and Image SynthesisModel Reduction and Neural NetworksNeural Networks and Reservoir Computing
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