Computational Modeling and Theoretical Analysis of Nonlinear Fractional Order Prey-Predator System

The focus of this manuscript is laid towards extracting insightful data embedded into web-based information which is crucial for various academic and commercialized application requirements. The study thereby introduces a robust computational modeling by means of computing knowledge from collaborative web-based unstructured information. For this purpose, this design is simplified with Fuzzy based matching algorithm and also with a set of procedures which reduces the computational effort to a significant extent. The numerical theoretical analysis shows that the effectiveness of the formulated model. It also shows that the formulated concept outperforms the baseline modeling by almost 50% when computational performance is concerned.

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Controllability of Flow-Conservation Transportation Networks with Fractional-Order Dynamics

Complexity ◽

10.1155/2021/8524984 ◽

2021 ◽

Vol 2021 ◽

pp. 1-13

Author(s):

Wei Chen ◽

Bo Zhou

Keyword(s):

Theoretical Analysis ◽

Fractional Derivative ◽

Exact Solutions ◽

Fractional Order ◽

Location Problem ◽

Transportation Networks ◽

Qr Decomposition ◽

Rank Condition ◽

Numerical Examples ◽

Flow Conservation

In this paper, we adapt the fractional derivative approach to formulate the flow-conservation transportation networks, which consider the propagation dynamics and the users’ behaviors in terms of route choices. We then investigate the controllability of the fractional-order transportation networks by employing the Popov-Belevitch-Hautus rank condition and the QR decomposition algorithm. Furthermore, we provide the exact solutions for the full controllability pricing controller location problem, which includes where to locate the controllers and how many controllers are required at the location positions. Finally, we illustrate two numerical examples to validate the theoretical analysis.

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Vibrational Resonance in an Overdamped System with a Fractional Order Potential Nonlinearity

International Journal of Bifurcation and Chaos ◽

10.1142/s0218127418500827 ◽

2018 ◽

Vol 28 (07) ◽

pp. 1850082 ◽

Cited By ~ 2

Author(s):

Jianhua Yang ◽

Dawen Huang ◽

Miguel A. F. Sanjuán ◽

Houguang Liu

Keyword(s):

Numerical Simulation ◽

Nonlinear System ◽

Theoretical Analysis ◽

Fractional Order ◽

Low Frequency ◽

Response Amplitude ◽

Resonance Phenomenon ◽

Vibrational Resonance ◽

Frequency Excitation ◽

Overdamped System

We investigate the vibrational resonance by the numerical simulation and theoretical analysis in an overdamped system with fractional order potential nonlinearities. The nonlinearity is a fractional power function with deflection, in which the response amplitude presents vibrational resonance phenomenon for any value of the fractional exponent. The response amplitude of vibrational resonance at low-frequency is deduced by the method of direct separation of slow and fast motions. The results derived from the theoretical analysis are in good agreement with those of numerical simulation. The response amplitude decreases with the increase of the fractional exponent for weak excitations. The amplitude of the high-frequency excitation can induce the vibrational resonance to achieve the optimal response amplitude. For the overdamped systems, the nonlinearity is the crucial and necessary condition to induce vibrational resonance. The response amplitude in the nonlinear system is usually not larger than that in the corresponding linear system. Hence, the nonlinearity is not a sufficient factor to amplify the response to the low-frequency excitation. Furthermore, the resonance may be also induced by only a single excitation acting on the nonlinear system. The theoretical analysis further proves the correctness of the numerical simulation. The results might be valuable in weak signal processing.

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Modeling and Analysis of the Fractional-Order Flyback Converter in Continuous Conduction Mode by Caputo Fractional Calculus

Electronics ◽

10.3390/electronics9091544 ◽

2020 ◽

Vol 9 (9) ◽

pp. 1544

Author(s):

Chen Yang ◽

Fan Xie ◽

Yanfeng Chen ◽

Wenxun Xiao ◽

Bo Zhang

Keyword(s):

Theoretical Analysis ◽

Fractional Order ◽

Transfer Functions ◽

Circuit Simulation ◽

Mutual Inductance ◽

Power Electronic ◽

Power Electronic Converters ◽

Flyback Converter ◽

Conduction Mode ◽

Continuous Conduction Mode

In order to obtain more realistic characteristics of the converter, a fractional-order inductor and capacitor are used in the modeling of power electronic converters. However, few researches focus on power electronic converters with a fractional-order mutual inductance. This paper introduces a fractional-order flyback converter with a fractional-order mutual inductance and a fractional-order capacitor. The equivalent circuit model of the fractional-order mutual inductance is derived. Then, the state-space average model of the fractional-order flyback converter in continuous conduction mode (CCM) are established. Moreover, direct current (DC) analysis and alternating current (AC) analysis are performed under the Caputo fractional definition. Theoretical analysis shows that the orders have an important influence on the ripple, the CCM operating condition and transfer functions. Finally, the results of circuit simulation and numerical calculation are compared to verify the correctness of the theoretical analysis and the validity of the model. The simulation results show that the fractional-order flyback converter exhibits smaller overshoot, shorter setting time and higher design freedom compared with the integer-order flyback converter.

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Control of amplitude death by coupling range in a network of fractional-order oscillators

International Journal of Modern Physics B ◽

10.1142/s0217979220503038 ◽

2020 ◽

Vol 34 (31) ◽

pp. 2050303

Author(s):

Rui Xiao ◽

Zhongkui Sun

Keyword(s):

Theoretical Analysis ◽

Numerical Simulations ◽

Fractional Order ◽

Coupling Strength ◽

Low Frequency ◽

System Size ◽

Coupled Systems ◽

Amplitude Death ◽

Function Relationship ◽

The Relationship

We investigate the oscillating dynamics in a ring of network of nonlocally delay-coupled fractional-order Stuart-Landau oscillators. It is concluded that with the increasing of coupling range, the structures of death islands go from richness to simplistic, nevertheless, the area of amplitude death (AD) state is expanded along coupling delay and coupling strength directions. The increased coupling range can prompt the coupled systems with low frequency to occur AD. When system size varies, the area of death islands changes periodically, and the linear function relationship between periodic length and coupling range can be deduced. Thus, one can modulate the oscillating dynamics by adjusting the relationship between coupling range and system size. Furthermore, the results of numerical simulations are consistent with theoretical analysis.

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