Abstract

We examine the usefulness of applying neural networks as a variational state ansatz for many-body quantum systems in the context of quantum information-processing tasks. In the neural network state ansatz, the complex amplitude function of a quantum state is computed by a neural network. The resulting multipartite entanglement structure captured by this ansatz has proven rich enough to describe the ground states and unitary dynamics of various physical systems of interest. In the present paper, we initiate the study of neural network states in quantum information-processing tasks. We demonstrate that neural network states are capable of efficiently representing quantum codes for quantum information transmission and quantum error correction, supplying further evidence for the usefulness of neural network states to describe multipartite entanglement. In particular, we show the following main results: (a) neural network states yield quantum codes with a high coherent information for two important quantum channels, the generalized amplitude damping channel and the dephrasure channel. These codes outperform all other known codes for these channels, and cannot be found using a direct parametrization of the quantum state. (b) For the depolarizing channel, the neural network state ansatz reliably finds the best known codes given by repetition codes. (c) Neural network states can be used to represent absolutely maximally entangled states, a special type of quantum error-correcting codes. In all three cases, the neural network state ansatz provides an efficient and versatile means as a variational parametrization of these highly entangled states.

Highlights

  • The exponential growth of the Hilbert space dimension in the number of particles is both a blessing and curse for quantum science: On the one hand, it is crucial to the widely-believed computational advantage of quantum computers over classical ones, but on the other hand it renders many questions about properties of many-body systems intractable

  • We demonstrate that neural network states with only polynomially many parameters in the system size are capable of representing quantum codes for quantum information transmission and quantum error correction

  • For the generalized amplitude damping channel, the new codes increase the threshold of the channel, i.e., the boundary of the interval in the parameter space with positive quantum capacity

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Summary

Introduction

The exponential growth of the Hilbert space dimension in the number of particles is both a blessing and curse for quantum science: On the one hand, it is crucial to the widely-believed computational advantage of quantum computers over classical ones, but on the other hand it renders many questions about properties of many-body systems intractable. We know that the “physical” corner of this Hilbert space has to be small: local Hamiltonians with highly-entangled ground states only require a polynomial number of parameters to describe, as do quantum circuits of polynomial depth. This fact motivates the use of variational representations of quantum states to solve a large class of problems. For gapped one-dimensional systems (which follow an entanglement entropy area law), one can use matrix product states (MPS) with polynomial bond dimension to efficiently represent ground states [FNW92; LVV15; Ara+13]. Other tensor network states include MERA and higher-dimensional variants such as PEPS—applied e.g. in the context of renormalization [Vid; VC04], and proven successful as part of numerical techniques [Oru14]

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