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Dynamics, Volume 3, Issue 1 (March 2023) – 12 articles

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12 pages, 3283 KiB  
Article
Chaotic van der Pol Oscillator Control Algorithm Comparison
by Lauren Ribordy and Timothy Sands
Dynamics 2023, 3(1), 202-213; https://doi.org/10.3390/dynamics3010012 - 19 Mar 2023
Cited by 1 | Viewed by 2022
Abstract
The damped van der Pol oscillator is a chaotic non-linear system. Small perturbations in initial conditions may result in wildly different trajectories. Controlling, or forcing, the behavior of a van der Pol oscillator is difficult to achieve through traditional adaptive control methods. Connecting [...] Read more.
The damped van der Pol oscillator is a chaotic non-linear system. Small perturbations in initial conditions may result in wildly different trajectories. Controlling, or forcing, the behavior of a van der Pol oscillator is difficult to achieve through traditional adaptive control methods. Connecting two van der Pol oscillators together where the output of one oscillator, the driver, drives the behavior of its partner, the responder, is a proven technique for controlling the van der Pol oscillator. Deterministic artificial intelligence is a feedforward and feedback control method that leverages the known physics of the van der Pol system to learn optimal system parameters for the forcing function. We assessed the performance of deterministic artificial intelligence employing three different online parameter estimation algorithms. Our evaluation criteria include mean absolute error between the target trajectory and the response oscillator trajectory over time. Two algorithms performed better than the benchmark with necessary discussion of the conditions under which they perform best. Recursive least squares with exponential forgetting had the lowest mean absolute error overall, with a 2.46% reduction in error compared to the baseline, feedforward without deterministic artificial intelligence. While least mean squares with normalized gradient adaptation had worse initial error in the first 10% of the simulation, after that point it exhibited consistently lower error. Over the last 90% of the simulation, deterministic artificial intelligence with least mean squares with normalized gradient adaptation achieved a 48.7% reduction in mean absolute error compared to baseline. Full article
(This article belongs to the Special Issue Theory and Applications in Nonlinear Oscillators)
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31 pages, 511 KiB  
Article
Moderate Averaged Deviations for a Multi-Scale System with Jumps and Memory
by André de Oliveira Gomes and Pedro Catuogno
Dynamics 2023, 3(1), 171-201; https://doi.org/10.3390/dynamics3010011 - 14 Mar 2023
Cited by 1 | Viewed by 1261
Abstract
This work studies a two-time-scale functional system given by two jump diffusions under the scale separation by a small parameter ε0. The coefficients of the equations that govern the dynamics of the system depend on the segment process of the [...] Read more.
This work studies a two-time-scale functional system given by two jump diffusions under the scale separation by a small parameter ε0. The coefficients of the equations that govern the dynamics of the system depend on the segment process of the slow variable (responsible for capturing delay effects on the slow component) and on the state of the fast variable. We derive a moderate deviation principle for the slow component of the system in the small noise limit using the weak convergence approach. The rate function is written in terms of the averaged dynamics associated with the multi-scale system. The core of the proof of the moderate deviation principle is the establishment of an averaging principle for the auxiliary controlled processes associated with the slow variable in the framework of the weak convergence approach. The controlled version of the averaging principle for the jump multi-scale diffusion relies on a discretization method inspired by the classical Khasminkii’s averaging principle. Full article
(This article belongs to the Topic Advances in Nonlinear Dynamics: Methods and Applications)
19 pages, 350 KiB  
Article
Existence for Nonlinear Fourth-Order Two-Point Boundary Value Problems
by Ravi Agarwal, Gabriela Mihaylova and Petio Kelevedjiev
Dynamics 2023, 3(1), 152-170; https://doi.org/10.3390/dynamics3010010 - 13 Mar 2023
Cited by 1 | Viewed by 990
Abstract
The present paper is devoted to the solvability of various two-point boundary value problems for the equation y(4)=f(t,y,y,y,y), where the nonlinearity f may [...] Read more.
The present paper is devoted to the solvability of various two-point boundary value problems for the equation y(4)=f(t,y,y,y,y), where the nonlinearity f may be defined on a bounded set and is needed to be continuous on a suitable subset of its domain. The established existence results guarantee not just a solution to the considered boundary value problems but also guarantee the existence of monotone solutions with suitable signs and curvature. The obtained results rely on a basic existence theorem, which is a variant of a theorem due to A. Granas, R. Guenther and J. Lee. The a priori bounds necessary for the application of the basic theorem are provided by the barrier strip technique. The existence results are illustrated with examples. Full article
15 pages, 665 KiB  
Article
Search for Damped Oscillating Structures from Charged Pion Electromagnetic Form Factor Data
by Erik Bartoš, Stanislav Dubnička and Anna Zuzana Dubničková
Dynamics 2023, 3(1), 137-151; https://doi.org/10.3390/dynamics3010009 - 04 Mar 2023
Cited by 1 | Viewed by 960
Abstract
The damped oscillating structures recently revealed by a three parametric formula from the proton “effective” form factor data extracted of the measured total cross section σtotbare(e+epp¯) [...] Read more.
The damped oscillating structures recently revealed by a three parametric formula from the proton “effective” form factor data extracted of the measured total cross section σtotbare(e+epp¯) still seem to have an unknown origin. The conjectures of their direct manifestation of the quark-gluon structure of the proton indicate that they are not specific only of the proton and neutron, but they have to be one’s own, similar to other hadrons. Therefore, the oscillatory structures from the charged pion electromagnetic form factor timelike data, extracted of the process e+eπ+π are investigated by using the same procedure as in the case of the proton. The analysis shows the appearance of the oscillating structures in the description of the charged pion electromagnetic form factor timelike data by three parametric formula with a rather large value of χ2/ndf, while the description of the data by the physically well-founded Unitary and Analytic model has not revealed any damped oscillating structures. From the obtained result on the most simple object of strong interactions, one can conclude that damped oscillating structures received from the “effective” proton form factor data are probably generated by a utilization of the improper three parametric formula which does not describe these data with sufficient precision. Full article
(This article belongs to the Special Issue Recent Advances in Dynamic Phenomena)
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22 pages, 4124 KiB  
Article
Enhancing Bayesian Approaches in the Cognitive and Neural Sciences via Complex Dynamical Systems Theory
by Luis H. Favela and Mary Jean Amon
Dynamics 2023, 3(1), 115-136; https://doi.org/10.3390/dynamics3010008 - 01 Mar 2023
Cited by 1 | Viewed by 2199
Abstract
In the cognitive and neural sciences, Bayesianism refers to a collection of concepts and methods stemming from various implementations of Bayes’ theorem, which is a formal way to calculate the conditional probability of a hypothesis being true based on prior expectations and updating [...] Read more.
In the cognitive and neural sciences, Bayesianism refers to a collection of concepts and methods stemming from various implementations of Bayes’ theorem, which is a formal way to calculate the conditional probability of a hypothesis being true based on prior expectations and updating priors in the face of errors. Bayes’ theorem has been fruitfully applied to describe and explain a wide range of cognitive and neural phenomena (e.g., visual perception and neural population activity) and is at the core of various theories (e.g., predictive processing). Despite these successes, we claim that Bayesianism has two interrelated shortcomings: its calculations and models are predominantly linear and noise is assumed to be random and unstructured versus deterministic. We outline ways that Bayesianism can address those shortcomings: first, by making more central the nonlinearities characteristic of biological cognitive systems, and second, by treating noise not as random and unstructured dynamics, but as the kind of structured nonlinearities of complex dynamical systems (e.g., chaos and fractals). We provide bistable visual percepts as an example of a real-world phenomenon that demonstrates the fruitfulness of integrating complex dynamical systems theory in Bayesian treatments of perception. Doing so facilitates a Bayesianism that is more capable of explaining a number of currently out-of-reach natural phenomena on their own, biologically realistic terms. Full article
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19 pages, 1518 KiB  
Article
An Energy-Based Complex Brain Network Model—Part 1: Local Electrophysiological Dynamics
by Chun-Lin Yang, Nandan Shettigar and C. Steve Suh
Dynamics 2023, 3(1), 96-114; https://doi.org/10.3390/dynamics3010007 - 20 Feb 2023
Cited by 1 | Viewed by 1216
Abstract
The human brain is a complex network of connected neurons whose dynamics are difficult to describe. Brain dynamics are the global manifestation of individual neuron dynamics and the synaptic coupling between neurons. Membrane potential is a function of synaptic dynamics and electrophysiological coupling, [...] Read more.
The human brain is a complex network of connected neurons whose dynamics are difficult to describe. Brain dynamics are the global manifestation of individual neuron dynamics and the synaptic coupling between neurons. Membrane potential is a function of synaptic dynamics and electrophysiological coupling, with the parameters of postsynaptic potential, action potential, and ion pump dynamics. By modelling synaptic dynamics using physical laws and the time evolution of membrane potential using energy, neuron dynamics can be described. This local depiction can be scaled up to describe mesoscopic and macroscopic hierarchical complexity in the brain. Modelling results are favorably compared with physiological observation and physically acquired action potential profiles as reported in the literature. Full article
(This article belongs to the Special Issue Recent Advances in Dynamic Phenomena)
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25 pages, 535 KiB  
Review
Dark Energy as a Natural Property of Cosmic Polytropes—A Tutorial
by Kostas Kleidis and Nikolaos K. Spyrou
Dynamics 2023, 3(1), 71-95; https://doi.org/10.3390/dynamics3010006 - 15 Feb 2023
Viewed by 1614
Abstract
A conventional approach to the dark energy (DE) concept is reviewed and discussed. According to it, there is absolutely no need for a novel DE component in the universe, provided that its matter–energy content is represented by a perfect fluid whose volume elements [...] Read more.
A conventional approach to the dark energy (DE) concept is reviewed and discussed. According to it, there is absolutely no need for a novel DE component in the universe, provided that its matter–energy content is represented by a perfect fluid whose volume elements perform polytropic flows. When the (thermodynamic) energy of the associated internal motions is taken into account as an additional source of the universal gravitational field, it compensates the DE needed to compromise spatial flatness in an accelerating universe. The unified model which is driven by a polytropic fluid not only interprets the observations associated with universe expansion but successfully confronts all the current issues of cosmological significance, thus arising as a viable alternative to the ΛCDM model. Full article
(This article belongs to the Special Issue Recent Advances in Dynamic Phenomena)
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11 pages, 2174 KiB  
Communication
Beyond the Light-Cone Propagation of Relativistic Wavefunctions: Numerical Results
by Xabier Gutierrez de la Ca and Alex Matzkin
Dynamics 2023, 3(1), 60-70; https://doi.org/10.3390/dynamics3010005 - 06 Feb 2023
Cited by 1 | Viewed by 1314
Abstract
It is known that relativistic wavefunctions formally propagate beyond the light cone when the propagator is limited to the positive energy sector. By construction, this is the case for solutions of the Salpeter (or relativistic Schrödinger) equation or for Klein–Gordon and Dirac wavefunctions [...] Read more.
It is known that relativistic wavefunctions formally propagate beyond the light cone when the propagator is limited to the positive energy sector. By construction, this is the case for solutions of the Salpeter (or relativistic Schrödinger) equation or for Klein–Gordon and Dirac wavefunctions defined in the Foldy–Wouthuysen representation. In this work, we quantitatively investigate the degree of non-causality for free propagation for different types of wavepackets that all initially have a compact spatial support. In the studied examples, we find that non-causality appears as a small transient effect that can in most cases be neglected. We display several numerical results and discuss the fundamental and practical consequences of our findings concerning this peculiar dynamical feature. Full article
(This article belongs to the Special Issue Recent Advances in Dynamic Phenomena)
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26 pages, 3881 KiB  
Article
Complex Network Methods for Plastic Deformation Dynamics in Metals
by Arnold Kiv, Arkady Bryukhanov, Vladimir Soloviev, Andrii Bielinskyi, Taras Kavetskyy, Dmytro Dyachok, Ivan Donchev and Viktor Lukashin
Dynamics 2023, 3(1), 34-59; https://doi.org/10.3390/dynamics3010004 - 30 Jan 2023
Cited by 1 | Viewed by 3178
Abstract
Plastic deformation of DC04 steel is regarded as a nonlinear, complex, irreversible, and self-organized process. The stress–strain time series analysis provided the possibility to identify areas of (quasi-)elastic deformation, plastic deformation, and necking. The latter two regions are the most informative. The area [...] Read more.
Plastic deformation of DC04 steel is regarded as a nonlinear, complex, irreversible, and self-organized process. The stress–strain time series analysis provided the possibility to identify areas of (quasi-)elastic deformation, plastic deformation, and necking. The latter two regions are the most informative. The area of inelastic deformation is reflected by collective, self-organized processes that lead to the formation of pores, and finally, the development of microcracks and a general crack as the cause of sample failure. Network measures for the quantitative assessment of the structural deformations in metals are proposed. Both spectral and topological measures of network complexity were found to be especially informative. According to our results, they can be used not only to classify the stages of plastic deformation, but also, they can be applied as a precursor of the material destruction process. Full article
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2 pages, 232 KiB  
Editorial
Acknowledgment to the Reviewers of Dynamics in 2022
by Dynamics Editorial Office
Dynamics 2023, 3(1), 32-33; https://doi.org/10.3390/dynamics3010003 - 18 Jan 2023
Viewed by 780
Abstract
High-quality academic publishing is built on rigorous peer review [...] Full article
14 pages, 306 KiB  
Article
Dynamical Invariant for Dissipative Systems via Complex Quantum Hydrodynamics
by Dieter Schuch and Moise Bonilla-Licea
Dynamics 2023, 3(1), 18-31; https://doi.org/10.3390/dynamics3010002 - 16 Jan 2023
Viewed by 1247
Abstract
For Hamiltonian systems with time-dependent potential, the Hamiltonian, and thus the energy, is no longer a constant of motion. However, for such systems as the parametric oscillator, i.e., an oscillator with time-dependent frequency ω(t), still, a dynamical invariant can [...] Read more.
For Hamiltonian systems with time-dependent potential, the Hamiltonian, and thus the energy, is no longer a constant of motion. However, for such systems as the parametric oscillator, i.e., an oscillator with time-dependent frequency ω(t), still, a dynamical invariant can be found that now has the dimension of action. The question, if such an invariant still exists after the addition of a dissipative friction force is analyzed for the classical as well as for the quantum mechanical case from different perspectives, particularly from that of a complex hydrodynamic formulation of quantum mechanics. Full article
(This article belongs to the Special Issue Recent Advances in Dynamic Phenomena)
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17 pages, 1214 KiB  
Article
Non-Equilibrium ϕ4 Theory in a Hierarchy: Towards Manipulating Holograms in Quantum Brain Dynamics
by Akihiro Nishiyama, Shigenori Tanaka and Jack A. Tuszynski
Dynamics 2023, 3(1), 1-17; https://doi.org/10.3390/dynamics3010001 - 04 Jan 2023
Cited by 7 | Viewed by 1662
Abstract
We describe non-equilibrium ϕ4 theory in a hierarchical manner to develop a method for manipulating coherent fields as a toy model of introducing control into Quantum Field Theory (QFT) of the brain, which is called Quantum Brain Dynamics (QBD). We begin with [...] Read more.
We describe non-equilibrium ϕ4 theory in a hierarchical manner to develop a method for manipulating coherent fields as a toy model of introducing control into Quantum Field Theory (QFT) of the brain, which is called Quantum Brain Dynamics (QBD). We begin with the Lagrangian density of ϕ4 model, where we adopt 2-Particle-Irreducible (2PI) effective action, and derive the Klein–Gordon equation of coherent fields with a damping term as an input–output equation proposed in areas of morphological computation or reservoir computing. Our analysis is extended to QFT in a hierarchy representing multiple layers covering cortex in a brain. We find that the desired target function is achieved via time-evolution in the Klein–Gordon equations in a hierarchy of numerical simulations when a signal in both the input and output prevails over noise in the intermediate layers. Our approach will be applied to control coherent fields in the systems (in a hierarchy) described in the QFT framework, with potential applications allowing the manipulation of quantum fields, especially holograms in QBD. We could then provide realistic physical degrees of freedom of a light–matter system in the contexts of quantum cognition and the associated free-energy principle. Full article
(This article belongs to the Special Issue Recent Advances in Dynamic Phenomena)
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