Studying dynamics in two-dimensional quantum lattices using tree tensor  network states

We analyze and discuss convergence properties of a numerically exact algorithm tailored to study the dynamics of interacting two-dimensional lattice systems. The method is based on the application of the time-dependent variational principle in a manifold of binary and quaternary Tree Tensor Network States. The approach is found to be competitive with existing matrix product state approaches. We discuss issues related to the convergence of the method, which could be relevant to a broader set of numerical techniques used for the study of two-dimensional systems.

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Computable Rényi mutual information: Area laws and correlations

Quantum ◽

10.22331/q-2021-09-14-541 ◽

2021 ◽

Vol 5 ◽

pp. 541

Author(s):

Samuel O. Scalet ◽

Álvaro M. Alhambra ◽

Georgios Styliaris ◽

J. Ignacio Cirac

Keyword(s):

Mutual Information ◽

Correlation Functions ◽

Quantum Correlations ◽

Matrix Product ◽

Many Body ◽

Von Neumann ◽

Tensor Network ◽

Network States ◽

Tensor Network States ◽

Area Law

The mutual information is a measure of classical and quantum correlations of great interest in quantum information. It is also relevant in quantum many-body physics, by virtue of satisfying an area law for thermal states and bounding all correlation functions. However, calculating it exactly or approximately is often challenging in practice. Here, we consider alternative definitions based on Rényi divergences. Their main advantage over their von Neumann counterpart is that they can be expressed as a variational problem whose cost function can be efficiently evaluated for families of states like matrix product operators while preserving all desirable properties of a measure of correlations. In particular, we show that they obey a thermal area law in great generality, and that they upper bound all correlation functions. We also investigate their behavior on certain tensor network states and on classical thermal distributions.

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Matrix Product State–Based Quantum Classifier

Neural Computation ◽

10.1162/neco_a_01202 ◽

2019 ◽

Vol 31 (7) ◽

pp. 1499-1517 ◽

Cited By ~ 2

Author(s):

Amandeep Singh Bhatia ◽

Mandeep Kaur Saggi ◽

Ajay Kumar ◽

Sushma Jain

Keyword(s):

Performance Metrics ◽

Quantum Computer ◽

Binary Classification ◽

Learning Ability ◽

Matrix Product ◽

Product State ◽

Data Set ◽

Matrix Product State ◽

Tensor Network ◽

Network States

Interest in quantum computing has increased significantly. Tensor network theory has become increasingly popular and widely used to simulate strongly entangled correlated systems. Matrix product state (MPS) is a well-designed class of tensor network states that plays an important role in processing quantum information. In this letter, we show that MPS, as a one-dimensional array of tensors, can be used to classify classical and quantum data. We have performed binary classification of the classical machine learning data set Iris encoded in a quantum state. We have also investigated its performance by considering different parameters on the ibmqx4 quantum computer and proved that MPS circuits can be used to attain better accuracy. Furthermore the learning ability of an MPS quantum classifier is tested to classify evapotranspiration (ET[Formula: see text]) for the Patiala meteorological station located in northern Punjab (India), using three years of a historical data set (Agri). We have used different performance metrics of classification to measure its capability. Finally, the results are plotted and the degree of correspondence among values of each sample is shown.

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Quantum phase transition in a two-dimensional quantum Ising model: Tensor network states and ground-state fidelity

Journal of Physics Conference Series ◽

10.1088/1742-6596/1087/5/052011 ◽

2018 ◽

Vol 1087 ◽

pp. 052011

Author(s):

Sheng-Hao Li ◽

Guo-Ping Lei

Keyword(s):

Phase Transition ◽

Ising Model ◽

Quantum Phase Transition ◽

Ground State ◽

Quantum Phase ◽

Two Dimensional ◽

Tensor Network ◽

Quantum Ising Model ◽

Network States ◽

Tensor Network States

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A local model of quantum Turing machines

Quantum Information and Computation ◽

10.26421/qic20.3-4-3 ◽

2020 ◽

Vol 20 (3&4) ◽

pp. 213-229

Author(s):

Dong-Sheng Wang

Keyword(s):

Information Processing ◽

Turing Machine ◽

Matrix Product ◽

Simulation Methods ◽

Turing Machines ◽

Matrix Product States ◽

Tensor Network ◽

Standard Models ◽

Network States ◽

Tensor Network States

The model of local Turing machines is introduced, including classical and quantum ones, in the framework of matrix-product states. The locality refers to the fact that at any instance of the computation the heads of a Turing machine have definite locations. The local Turing machines are shown to be equivalent to the corresponding circuit models and standard models of Turing machines by simulation methods. This work reveals the fundamental connection between tensor-network states and information processing.

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Plaquette renormalization scheme for tensor network states

Physical Review E ◽

10.1103/physreve.83.056703 ◽

2011 ◽

Vol 83 (5) ◽

Cited By ~ 14

Author(s):

Ling Wang ◽

Ying-Jer Kao ◽

Anders W. Sandvik

Keyword(s):

Renormalization Scheme ◽

Tensor Network ◽

Network States ◽

Tensor Network States

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Universal photonic quantum computation via time-delayed feedback

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1711003114 ◽

2017 ◽

Vol 114 (43) ◽

pp. 11362-11367 ◽

Cited By ~ 44

Author(s):

Hannes Pichler ◽

Soonwon Choi ◽

Peter Zoller ◽

Mikhail D. Lukin

Keyword(s):

Single Atom ◽

Many Body ◽

Cluster States ◽

Quantum Emitter ◽

Tensor Network ◽

Quantum Feedback ◽

Network States ◽

Tensor Network States ◽

Photonic Quantum Computation ◽

Time Delayed Feedback

We propose and analyze a deterministic protocol to generate two-dimensional photonic cluster states using a single quantum emitter via time-delayed quantum feedback. As a physical implementation, we consider a single atom or atom-like system coupled to a 1D waveguide with a distant mirror, where guided photons represent the qubits, while the mirror allows the implementation of feedback. We identify the class of many-body quantum states that can be produced using this approach and characterize them in terms of 2D tensor network states.

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