Fractional Dynamics Identification via Intelligent Unpacking of the Sample Autocovariance Function by Neural Networks

Fractional Dynamics Identification via Intelligent Unpacking of the Sample Autocovariance Function by Neural Networks

Many single-particle tracking data related to the motion in crowded environments exhibit anomalous diffusion behavior. This phenomenon can be described by different theoretical models. In this paper, fractional Brownian motion (FBM) was examined as the exemplary Gaussian process with fractional dyna...

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Main Authors: Dawid Szarek, Grzegorz Sikora, Michał Balcerek, Ireneusz Jabłoński, Agnieszka Wyłomańska
Format: Article
Language:English
Published: MDPI AG 2020-11-01
Series:Entropy
Subjects:
anomalous diffusion
fractional Brownian motion
estimation
autocovariance function
neural network
Monte Carlo simulations
Online Access:https://www.mdpi.com/1099-4300/22/11/1322
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spelling doaj-63ff2f0d89c441f9930af866c393200d2020-11-25T04:11:27ZengMDPI AGEntropy1099-43002020-11-01221322132210.3390/e22111322Fractional Dynamics Identification via Intelligent Unpacking of the Sample Autocovariance Function by Neural NetworksDawid Szarek0Grzegorz Sikora1Michał Balcerek2Ireneusz Jabłoński3Agnieszka Wyłomańska4Faculty of Pure and Applied Mathematics, Hugo Steinhaus Center, Wroclaw University of Science and Technology, Wybrzeże Wyspiańskiego 27, 50-370 Wroclaw, PolandFaculty of Pure and Applied Mathematics, Hugo Steinhaus Center, Wroclaw University of Science and Technology, Wybrzeże Wyspiańskiego 27, 50-370 Wroclaw, PolandFaculty of Pure and Applied Mathematics, Hugo Steinhaus Center, Wroclaw University of Science and Technology, Wybrzeże Wyspiańskiego 27, 50-370 Wroclaw, PolandDepartment of Electronics, Wroclaw University of Science and Technology, B. Prusa 53/55, 50-317 Wroclaw, PolandFaculty of Pure and Applied Mathematics, Hugo Steinhaus Center, Wroclaw University of Science and Technology, Wybrzeże Wyspiańskiego 27, 50-370 Wroclaw, PolandMany single-particle tracking data related to the motion in crowded environments exhibit anomalous diffusion behavior. This phenomenon can be described by different theoretical models. In this paper, fractional Brownian motion (FBM) was examined as the exemplary Gaussian process with fractional dynamics. The autocovariance function (ACVF) is a function that determines completely the Gaussian process. In the case of experimental data with anomalous dynamics, the main problem is first to recognize the type of anomaly and then to reconstruct properly the physical rules governing such a phenomenon. The challenge is to identify the process from short trajectory inputs. Various approaches to address this problem can be found in the literature, e.g., theoretical properties of the sample ACVF for a given process. This method is effective; however, it does not utilize all of the information contained in the sample ACVF for a given trajectory, i.e., only values of statistics for selected lags are used for identification. An evolution of this approach is proposed in this paper, where the process is determined based on the knowledge extracted from the ACVF. The designed method is intuitive and it uses information directly available in a new fashion. Moreover, the knowledge retrieval from the sample ACVF vector is enhanced with a learning-based scheme operating on the most informative subset of available lags, which is proven to be an effective encoder of the properties inherited in complex data. Finally, the robustness of the proposed algorithm for FBM is demonstrated with the use of Monte Carlo simulations.https://www.mdpi.com/1099-4300/22/11/1322anomalous diffusionfractional Brownian motionestimationautocovariance functionneural networkMonte Carlo simulations
collection DOAJ
language English
format Article
sources DOAJ
author Dawid Szarek
Grzegorz Sikora
Michał Balcerek
Ireneusz Jabłoński
Agnieszka Wyłomańska
spellingShingle Dawid Szarek
Grzegorz Sikora
Michał Balcerek
Ireneusz Jabłoński
Agnieszka Wyłomańska
Fractional Dynamics Identification via Intelligent Unpacking of the Sample Autocovariance Function by Neural Networks
Entropy
anomalous diffusion
fractional Brownian motion
estimation
autocovariance function
neural network
Monte Carlo simulations
author_facet Dawid Szarek
Grzegorz Sikora
Michał Balcerek
Ireneusz Jabłoński
Agnieszka Wyłomańska
author_sort Dawid Szarek
title Fractional Dynamics Identification via Intelligent Unpacking of the Sample Autocovariance Function by Neural Networks
title_short Fractional Dynamics Identification via Intelligent Unpacking of the Sample Autocovariance Function by Neural Networks
title_full Fractional Dynamics Identification via Intelligent Unpacking of the Sample Autocovariance Function by Neural Networks
title_fullStr Fractional Dynamics Identification via Intelligent Unpacking of the Sample Autocovariance Function by Neural Networks
title_full_unstemmed Fractional Dynamics Identification via Intelligent Unpacking of the Sample Autocovariance Function by Neural Networks
title_sort fractional dynamics identification via intelligent unpacking of the sample autocovariance function by neural networks
publisher MDPI AG
series Entropy
issn 1099-4300
publishDate 2020-11-01
description Many single-particle tracking data related to the motion in crowded environments exhibit anomalous diffusion behavior. This phenomenon can be described by different theoretical models. In this paper, fractional Brownian motion (FBM) was examined as the exemplary Gaussian process with fractional dynamics. The autocovariance function (ACVF) is a function that determines completely the Gaussian process. In the case of experimental data with anomalous dynamics, the main problem is first to recognize the type of anomaly and then to reconstruct properly the physical rules governing such a phenomenon. The challenge is to identify the process from short trajectory inputs. Various approaches to address this problem can be found in the literature, e.g., theoretical properties of the sample ACVF for a given process. This method is effective; however, it does not utilize all of the information contained in the sample ACVF for a given trajectory, i.e., only values of statistics for selected lags are used for identification. An evolution of this approach is proposed in this paper, where the process is determined based on the knowledge extracted from the ACVF. The designed method is intuitive and it uses information directly available in a new fashion. Moreover, the knowledge retrieval from the sample ACVF vector is enhanced with a learning-based scheme operating on the most informative subset of available lags, which is proven to be an effective encoder of the properties inherited in complex data. Finally, the robustness of the proposed algorithm for FBM is demonstrated with the use of Monte Carlo simulations.
topic anomalous diffusion
fractional Brownian motion
estimation
autocovariance function
neural network
Monte Carlo simulations
url https://www.mdpi.com/1099-4300/22/11/1322
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