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On the descriptive power of Neural-Networks as constrained Tensor Networks with exponentially large bond dimension

Mario Collura, Luca Dell'Anna, Timo Felser, Simone Montangero

2021SciPost Physics Core11 citationsDOIOpen Access PDF

Abstract

In many cases, neural networks can be mapped into tensor networks with an exponentially large bond dimension. Here, we compare different sub-classes of neural network states, with their mapped tensor network counterpart for studying the ground state of short-range Hamiltonians. We show that when mapping a neural network, the resulting tensor network is highly constrained and thus the neural network states do in general not deliver the naive expected drastic improvement against the state-of-the-art tensor network methods. We explicitly show this result in two paradigmatic examples, the 1D ferromagnetic Ising model and the 2D antiferromagnetic Heisenberg model, addressing the lack of a detailed comparison of the expressiveness of these increasingly popular, variational ans"atze.

Topics & Concepts

Tensor (intrinsic definition)Artificial neural networkIsing modelDimension (graph theory)State (computer science)MathematicsHeisenberg modelExponential growthPower (physics)Computer scienceStatistical physicsTopology (electrical circuits)Ground stateApplied mathematicsAntiferromagnetismPhysicsTensor productDimensionality reductionPower lawDiscrete mathematicsQuantum many-body systemsMachine Learning in Materials ScienceQuantum Computing Algorithms and Architecture