Revealing quantum chaos with machine learning

Kharkov, Ya. A.; Sotskov, Vadim; Karazeev, Anton; Kiktenko, Evgeniy O.; Fedorov, Aleksey K.

doi:10.1103/physrevb.101.064406

Cited by 35 publications

(31 citation statements)

References 64 publications

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“…AD today has numerous applications across a variety of domains. Examples include intrusion detection in cybersecurity [15]- [20], fraud detection in finance, insurance, healthcare, and telecommunication [21]- [27], industrial fault and damage detection [28]- [36], the monitoring of infrastructure [37], [38] and stock markets [39], [40], acoustic novelty detection [41]- [45], medical diagnosis [46]- [60] and disease outbreak detection [61], [62], event detection in the earth sciences [63]- [68], and scientific discovery in chemistry [69], [70], bioinformatics [71], genetics [72], [73], physics [74], [75], and astronomy [76]- [79]. The data available in these domains is continually growing in size.…”

Section: Introductionmentioning

confidence: 99%

A Unifying Review of Deep and Shallow Anomaly Detection

et al. 2021

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Section: Introductionmentioning

confidence: 99%

A Unifying Review of Deep and Shallow Anomaly Detection

et al. 2021

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“…Artificial neural networks (NNs), one of the most efficient and widely used tools of ML [8], are currently at the frontier of research activity. It has been shown that they are capable of predicting phase transitions and critical temperatures [9][10][11][12][13][14][15][16][17][18][19], learning topological indices of quantum phases [20][21][22][23][24][25][26], efficiently representing many-body states [27][28][29][30][31][32][33][34], improving known numerical computational methods [35][36][37], and decoding topological quantum correcting codes [38][39][40][41][42].…”

Section: Introductionmentioning

confidence: 99%

Unsupervised learning using topological data augmentation

Balabanov

Granath

2020

Phys. Rev. Research

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Unsupervised machine learning is a cornerstone of artificial intelligence as it provides algorithms capable of learning tasks, such as classification of data, without explicit human assistance. We present an unsupervised deep learning protocol for finding topological indices of quantum systems. The core of the proposed scheme is a "topological data augmentation" procedure that uses seed objects to generate ensembles of topologically equivalent data. Such data, assigned with dummy labels, can then be used to train a neural network classifier for sorting arbitrary objects into topological equivalence classes. Importantly, we also show how to retrieve the local quantities corresponding to the learned topological indices from the intermediate outputs of the trained network. Our protocol is explicitly illustrated on two-band insulators in one and two dimensions, characterized by a winding number and a Chern number respectively. Using the augmentation technique also in the classification step, to classify a family of topologically equivalent objects instead of a single object, we can achieve accuracy arbitrarily close to 100% even for indices outside the training regime. Apart from the method's applicability to topological classification, it also provides a new perspective on data augmentation in supervised machine learning, where given sufficient mathematical structure the set of category-preserving deformations can be rigorously defined.

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“…transition) sampling problem. In addition, study of quantum many body systems using Machine Learning is applied to simulation of the quantum spin dynamics 26 , 27 , identifying phase transitions 28 , and solves the exponential complexity of the many body problem in quantum systems 29 .…”

Section: Introductionmentioning

confidence: 99%

“…www.nature.com/scientificreports/ is applied to simulation of the quantum spin dynamics 26,27 , identifying phase transitions 28 , and solves the exponential complexity of the many body problem in quantum systems 29 .…”

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confidence: 99%

Accelerated spin dynamics using deep learning corrections

Park

Kwak

Lee

2020

Sci Rep

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theoretical models capture very precisely the behaviour of magnetic materials at the microscopic level. This makes computer simulations of magnetic materials, such as spin dynamics simulations, accurately mimic experimental results. New approaches to efficient spin dynamics simulations are limited by integration time step barrier to solving the equations-of-motions of many-body problems. Using a short time step leads to an accurate but inefficient simulation regime whereas using a large time step leads to accumulation of numerical errors that render the whole simulation useless. In this paper, we use a Deep Learning method to compute the numerical errors of each large time step and use these computed errors to make corrections to achieve higher accuracy in our spin dynamics. We validate our method on the 3D Ferromagnetic Heisenberg cubic lattice over a range of temperatures. Here we show that the Deep Learning method can accelerate the simulation speed by 10 times while maintaining simulation accuracy and overcome the limitations of requiring small time steps in spin dynamic simulations. Magnetic materials have a wide range of industrial applications such as in Nd-Fe-B-type permanent magnets used for motors in hybrid cars 1,2 , magnetoresistive random access memory (MRAM) based on the storage of data in stable magnetic states 3 , ultrafast spins dynamics in magnetic nanostructures 4,5 , heat assisted magnetic recording and ferromagnetic resonance methods for increasing the storage density of hard disk drives 6,7 , exchange bias related to magnetic recording 8 , and magnetocaloric materials for refrigeration technologies 1. Understanding the underlying physics of magnetic material enables us to develop much better applications. In particular, the study of the properties of these magnetic materials is performed experimentally by using neutron scattering 9. Magnetic properties of materials are also studied theoretically using computational methods. Spin dynamics simulations 10 are powerful tools for understanding fundamental properties of magnetic materials that can be verified by experimental methods. In spin dynamics simulations, classical equations of motion of spin systems are solved numerically using well known integrators such as leapfrog, Verlet, predictor-corrector, and Runge-Kutta methods 11-13. The accuracy of these simulations depends on a time integration step size. If a large time step is used, the accumulated truncation error becomes larger. Conversely, using a short time step is very computationally demanding. So, it is important to find a trade off between speed and accuracy. Symplectic methods 14,15 are among the most useful time integrators for spin dynamics simulations. The numerical solutions of symplectic methods have properties of the time reversibility and the energy conservation. For example, high order Suzuki-Trotter decomposition method, one of the symplectic methods, allows for larger time step with limited error in its computation. In this paper, we seek to enhance the time integration st...

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Revealing quantum chaos with machine learning

Cited by 35 publications

References 64 publications

A Unifying Review of Deep and Shallow Anomaly Detection

A Unifying Review of Deep and Shallow Anomaly Detection

Unsupervised learning using topological data augmentation

Accelerated spin dynamics using deep learning corrections

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