Litcius/Paper detail

Supervised learning in Hamiltonian reconstruction from local measurements on eigenstates

Chenfeng Cao, Shi-Yao Hou, Ningping Cao, Bei Zeng

2020Journal of Physics Condensed Matter22 citationsDOIOpen Access PDF

Abstract

Reconstructing a system Hamiltonian through measurements on its eigenstates is an important inverse problem in quantum physics. Recently, it was shown that generic many-body local Hamiltonians can be recovered by local measurements without knowing the values of the correlation functions. In this work, we discuss this problem in more depth for different systems and apply supervised learning method via neural networks to solve it. For low-lying eigenstates, the inverse problem is well-posed, neural networks turn out to be efficient and scalable even with a shallow network and a small data set. For middle-lying eigenstates, the problem is ill-posed, we present a modified method based on transfer learning accordingly. Neural networks can also efficiently generate appropriate initial points for numerical optimization based on the BFGS method.

Topics & Concepts

Artificial neural networkEigenvalues and eigenvectorsBroyden–Fletcher–Goldfarb–Shanno algorithmInverse problemHamiltonian (control theory)Inverse scattering problemSupervised learningInverseMathematicsScalabilityComputer scienceComputationQuantumArtificial intelligenceAlgorithmOptimization problemApplied mathematicsMaxima and minimaData pointMathematical optimizationInversion (geology)Position (finance)Semi-supervised learningQuantum many-body systemsMachine Learning in Materials ScienceModel Reduction and Neural Networks