Time-varying integro-differential inclusions with Clarke sub-differential and non-local initial conditions: existence and approximate controllability

A transform approach based on a variable initial time (VIT) formulation is developed for discrete-time signals and linear time-varying discrete-time systems or digital filters. The VIT transform is a formal power series in z−1, which converts functions given by linear time-varying difference equations into left polynomial fractions with variable coefficients, and with initial conditions incorporated into the framework. It is shown that the transform satisfies a number of properties that are analogous to those of the ordinary z-transform, and that it is possible to do scaling of z−i by time functions, which results in left-fraction forms for the transform of a large class of functions including sinusoids with general time-varying amplitudes and frequencies. Using the extended right Euclidean algorithm in a skew polynomial ring with time-varying coefficients, it is shown that a sum of left polynomial fractions can be written as a single fraction, which results in linear time-varying recursions for the inverse transform of the combined fraction. The extraction of a first-order term from a given polynomial fraction is carried out in terms of the evaluation of zi at time functions. In the application to linear time-varying systems, it is proved that the VIT transform of the system output is equal to the product of the VIT transform of the input and the VIT transform of the unit-pulse response function. For systems given by a time-varying moving average or an autoregressive model, the transform framework is used to determine the steady-state output response resulting from various signal inputs such as the step and cosine functions.

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Results on approximate controllability of Sobolev-type fractional neutral differential inclusions of Clarke subdifferential type

Chaos Solitons & Fractals ◽

10.1016/j.chaos.2021.111264 ◽

2021 ◽

Vol 151 ◽

pp. 111264

Author(s):

K. Kavitha ◽

V. Vijayakumar ◽

Anurag Shukla ◽

Kottakkaran Sooppy Nisar ◽

R. Udhayakumar

Keyword(s):

Differential Inclusions ◽

Approximate Controllability ◽

Clarke Subdifferential ◽

Sobolev Type

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Asymptotic Stability of Nonlinear Discrete Fractional Pantograph Equations with Non-Local Initial Conditions

Symmetry ◽

10.3390/sym13030473 ◽

2021 ◽

Vol 13 (3) ◽

pp. 473

Author(s):

Jehad Alzabut ◽

A. George Maria Selvam ◽

Rami Ahmad El-Nabulsi ◽

D. Vignesh ◽

Mohammad Esmael Samei

Keyword(s):

Fixed Point ◽

Asymptotic Stability ◽

Fixed Point Theorems ◽

Initial Conditions ◽

Current Collector ◽

Stability Of Solutions ◽

Electric Bus ◽

Pantograph Equation ◽

Non Local

Pantograph, the technological successor of trolley poles, is an overhead current collector of electric bus, electric trains, and trams. In this work, we consider the discrete fractional pantograph equation of the form Δ*β[k](t)=wt+β,k(t+β),k(λ(t+β)), with condition k(0)=p[k] for t∈N1−β, 0<β≤1, λ∈(0,1) and investigate the properties of asymptotic stability of solutions. We will prove the main results by the aid of Krasnoselskii’s and generalized Banach fixed point theorems. Examples involving algorithms and illustrated graphs are presented to demonstrate the validity of our theoretical findings.

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Spatio-temporal integration in plant tropisms

Journal of The Royal Society Interface ◽

10.1098/rsif.2019.0038 ◽

2019 ◽

Vol 16 (154) ◽

pp. 20190038 ◽

Cited By ~ 6

Author(s):

Yasmine Meroz ◽

Renaud Bastien ◽

L. Mahadevan

Keyword(s):

Response Function ◽

Shoot Growth ◽

Analytic Solution ◽

Temporal Integration ◽

Time Varying ◽

Local Response ◽

History Of ◽

Non Local ◽

Spatio Temporal ◽

Plant Shoots

Tropisms, growth-driven responses to environmental stimuli, cause plant organs to respond in space and time and reorient themselves. Classical experiments from nearly a century ago reveal that plant shoots respond to the integrated history of light and gravity stimuli rather than just responding instantaneously. We introduce a temporally non-local response function for the dynamics of shoot growth formulated as an integro-differential equation whose solution allows us to qualitatively reproduce experimental observations associated with intermittent and unsteady stimuli. Furthermore, an analytic solution for the case of a pulse stimulus expresses the response function as a function of experimentally tractable variables, which we calculate for the case of the phototropic response of Arabidopsis hypocotyls. All together, our model enables us to predict tropic responses to time-varying stimuli, manifested in temporal integration phenomena, and sets the stage for the incorporation of additional effects such as multiple stimuli, gravitational sagging, etc.

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Transformation of Uncertain Linear Systems with Real Eigenvalues into Cooperative Form: The Case of Constant and Time-Varying Bounded Parameters

Algorithms ◽

10.3390/a14030085 ◽

2021 ◽

Vol 14 (3) ◽

pp. 85

Author(s):

Andreas Rauh ◽

Julia Kersten

Keyword(s):

Linear Systems ◽

Initial Conditions ◽

A Priori ◽

Real Life ◽

Reachability Analysis ◽

Interval Methods ◽

Space Representation ◽

Uncertain Parameters ◽

Time Varying ◽

Similarity Transformations

Continuous-time linear systems with uncertain parameters are widely used for modeling real-life processes. The uncertain parameters, contained in the system and input matrices, can be constant or time-varying. In the latter case, they may represent state dependencies of these matrices. Assuming bounded uncertainties, interval methods become applicable for a verified reachability analysis, for feasibility analysis of feedback controllers, or for the design of robust set-valued state estimators. The evaluation of these system models becomes computationally efficient after a transformation into a cooperative state-space representation, where the dynamics satisfy certain monotonicity properties with respect to the initial conditions. To obtain such representations, similarity transformations are required which are not trivial to find for sufficiently wide a-priori bounds of the uncertain parameters. This paper deals with the derivation and algorithmic comparison of two different transformation techniques for which their applicability to processes with constant and time-varying parameters has to be distinguished. An interval-based reachability analysis of the states of a simple electric step-down converter concludes this paper.

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Evaluation of Costate Variables and Performance Index to the Feedback Path for a Time Varying System by Norm Linear Bounded Linear Differential Inclusions Method

Learning and Analytics in Intelligent Systems - Intelligent Techniques and Applications in Science and Technology ◽

10.1007/978-3-030-42363-6_97 ◽

2020 ◽

pp. 845-852

Author(s):

Nirmalya Chandra ◽

Achintya Das

Keyword(s):

Performance Index ◽

Differential Inclusions ◽

Time Varying ◽

Bounded Linear ◽

Feedback Path ◽

Linear Differential Inclusions ◽

Linear Differential ◽

And Performance

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Complexity In Psychological Self-Ratings: Implications for research and practice

10.31234/osf.io/fbta8 ◽

2020 ◽

Author(s):

Merlijn Olthof ◽

Fred Hasselman ◽

Anna Lichtwarck-Aschoff

Keyword(s):

Complex Systems ◽

Systems Approach ◽

Complex Dynamics ◽

Initial Conditions ◽

Regime Shifts ◽

Fundamental Aspect ◽

Time Varying ◽

Term Prediction ◽

Sensitive Dependence

Background: Psychopathology research is changing focus from group-based ‘disease models’ to a personalized approach inspired by complex systems theories. This approach, which has already produced novel and valuable insights into the complex nature of psychopathology, often relies on repeated self-ratings of individual patients. So far it has been unknown whether such self-ratings, the presumed observables of the individual patient as a complex system, actually display complex dynamics. We examine this basic assumption of a complex systems approach to psychopathology by testing repeated self-ratings for three markers of complexity: memory, the presence of (time-varying) short- and long-range temporal correlations, regime shifts, transitions between different dynamic regimes, and, sensitive dependence on initial conditions, also known as the ‘butterfly effect’, the divergence of initially similar trajectories.Methods: We analysed repeated self-ratings (1476 time points) from a single patient for the three markers of complexity using Bartels rank test, (partial) autocorrelation functions, time-varying autoregression, a non-stationarity test, change point analysis and the Sugihara-May algorithm.Results: Self-ratings concerning psychological states (e.g., the item ‘I feel down’) exhibited all complexity markers: time-varying short- and long-term memory, multiple regime shifts and sensitive dependence on initial conditions. Unexpectedly, self-ratings concerning physical sensations (e.g., the item ‘I am hungry’) exhibited less complex dynamics and their behaviour was more similar to random variables. Conclusions: Psychological self-ratings display complex dynamics. The presence of complexity in repeated self-ratings means that we have to acknowledge that (1) repeated self-ratings yield a complex pattern of data and not a set of (nearly) independent data points, (2) humans are ‘moving targets’ whose self-ratings display non-stationary change processes including regime shifts, and (3) long-term prediction of individual trajectories may be fundamentally impossible. These findings point to a limitation of popular statistical time series models whose assumptions are violated by the presence of these complexity markers. We conclude that a complex systems approach to mental health should appreciate complexity as a fundamental aspect of psychopathology research by adopting the models and methods of complexity science. Promising first steps in this direction, such as research on real-time process-monitoring, short-term prediction, and just-in-time interventions, are discussed.

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Solvability of control problem for fractional nonlinear differential inclusions with nonlocal conditions

Nonlinear Analysis Modelling and Control ◽

10.15388/na.2019.4.2 ◽

2019 ◽

Vol 24 (4) ◽

Author(s):

Alka Chadha ◽

Rathinasamy Sakthivel ◽

Swaroop Nandan Bora

Keyword(s):

Differential Inclusions ◽

Approximate Controllability ◽

Measure Of Noncompactness ◽

Nonlocal Conditions ◽

Sufficient Conditions ◽

Fractional Differential Inclusions ◽

Multivalued Maps ◽

Nonlinear Differential Inclusions ◽

Approximately Controllable ◽

Fractional Differential

In this paper, we study the approximate controllability of nonlocal fractional differential inclusions involving the Caputo fractional derivative of order q ∈ (1,2) in a Hilbert space. Utilizing measure of noncompactness and multivalued fixed point strategy, a new set of sufficient conditions is obtained to ensure the approximate controllability of nonlocal fractional differential inclusions when the multivalued maps are convex. Precisely, the results are developed under the assumption that the corresponding linear system is approximately controllable.

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