No nonlocality. No fractional derivative

Tarasov, Vasily E.

doi:10.1016/j.cnsns.2018.02.019

Cited by 181 publications

(112 citation statements)

References 19 publications

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“…Several paradoxes involving the GFD with regular kernels have been pointed out in [21,14,22,5]. In [15] it has been shown that the models involving the GFD with regular kernels poorly reflect the real world data.…”

Section: Introductionmentioning

confidence: 99%

A Comment on a Controversial Issue: A Generalized Fractional Derivative Cannot Have a Regular Kernel

Hanyga

2020

Fract Calc Appl Anal

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The problem whether a given pair of functions can be used as the kernels of a generalized fractional derivative and the associated generalized fractional integral is reduced to the problem of existence of a solution to the Sonine equation. It is shown for some selected classes of functions that a necessary condition for a function to be the kernel of a fractional derivative is an integrable singularity at 0. It is shown that locally integrable completely monotone functions satisfy the Sonine equation if and only if they are singular at 0. MSC 2010 : 26A33, 34A99Notations.

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Section: Introductionmentioning

confidence: 99%

A Comment on a Controversial Issue: A Generalized Fractional Derivative Cannot Have a Regular Kernel

Hanyga

2020

Fract Calc Appl Anal

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“…• there is no memory term and the approximation of the solution is obtained by using just local information; • the numerical approximation, which is obtained by means of linear interpolant polynomials, is claimed to converge to the exact solution with order 3 under the simple assumption that f (t, y(t)) is bounded. It is a well-known fact that fractional derivatives are nonlocal operators and, as discussed in some recent papers [15,16], nonlocality is an essential, distinctive and inviolable feature of fractional-order operators.…”

Section: Introductionmentioning

confidence: 99%

Neglecting nonlocality leads to unreliable numerical methods for fractional differential equations

Garrappa

2019

Communications in Nonlinear Science and Numerical Simulation

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In the paper titled "New numerical approach for fractional differential equations" by A. Atangana and K.M. Owolabi [Math. Model. Nat. Phenom., 13(1), 2018], it is presented a method for the numerical solution of some fractional differential equations. The numerical approximation is obtained by using just local information and the scheme does not present a memory term; moreover, it is claimed that third-order convergence is surprisingly obtained by simply using linear polynomial approximations. In this note we show that methods of this kind are not reliable and lead to completely wrong results since the nonlocal nature of fractional differential operators cannot be neglected. We illustrate the main weaknesses in the derivation and analysis of the method in order to warn other researchers and scientist to overlook this and other methods devised on similar basis and avoid their use for the numerical simulation of fractional differential equations.

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“…Theorem 2.11 (Fractional Gradient Descent). Let f be as in (13). Then, the left-sigmoidal fractional-order gradient method (13) converges to the true critical point t * .…”

Section: Proof Proof From (8) Integrating By Parts Yieldsmentioning

confidence: 99%