Abstract
Reliable methods for the classification and quantification of quantum entanglement are fundamental to understanding its exploitation in quantum technologies. One such method, known as separable neural network quantum states (SNNS), employs a neural network inspired parameterization of quantum states whose entanglement properties are explicitly programmable. Combined with generative machine learning methods, this ansatz allows for the study of very specific forms of entanglement which can be used to infer/measure entanglement properties of target quantum states. In this work, we extend the use of SNNS to mixed, multipartite states, providing a versatile and efficient tool for the investigation of intricately entangled quantum systems. We illustrate the effectiveness of our method through a number of examples, such as the computation of novel tripartite entanglement measures, and the approximation of ultimate upper bounds for qudit channel capacities.
Highlights
In this paper, we generalize these results to mixed, d-dimensional quantum states
We have generalized the concept of network quantum states (NNS) with programmable separability to mixed, d-dimensional quantum states
We discussed a number of neural network architectures for the description of quantum states, and detailed how their entanglement properties may be controlled via constraints placed on network connectivity
Summary
Original content from this work may be used under the terms of the Creative Commons Attribution 4.0 licence. Any further distribution of this work must maintain attribution to the author(s) and the title of the work, journal citation and DOI. Keywords: entanglement classification, entanglement measures, machine learning, neural network quantum states
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