Definitions of Fractional derivative

In summary, There are several definitions, including the Riemann-Liouville differintegral, the Grunwald-Letnikov derivative, the Hadamard derivative, and the Caputo derivative, for defining fractional derivatives of functions x^{a}f(x) for real or complex 'a'. All of these definitions are equivalent, but it can be inconvenient to have multiple definitions for the same concept. Additionally, the Riemann-Liouville differintegral requires extra calculations for integer values of m.
  • #1
Klaus_Hoffmann
86
1
how many definitions appart from the 'Riemann-Liouville differintegral' to define the fractional derivative of f(x) or [tex] x^{a}f(x) [/tex] for real or complex 'a' are them all equivalents??
 
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  • #2
The other variation is the Grunwald-Letnikov Derivative, and all definitions are equivalent. It's pretty pointless if you have 2 different definitions for the same thing..
 
  • #3
not pointless, but inconsistent.
 
  • #4
I heard also about Hadamard and Caputo derivatives for fractional calculus could anyone give a link with the definition?

a great inconvenient i see to Riemann-Liouville differintegral is the fact that for an integer m you must calculate expression [tex] \frac{d^{m}}{dx^{m}} [/tex]
 

Related to Definitions of Fractional derivative

What is a fractional derivative?

A fractional derivative is a mathematical operation that extends the concept of a derivative to non-integer orders. It is used to describe the rate of change of a function at a given point.

How is a fractional derivative different from a traditional derivative?

A traditional derivative is defined for integer orders, while a fractional derivative is defined for non-integer orders. Additionally, a traditional derivative gives the slope of a tangent line, while a fractional derivative gives the slope of a fractional tangent line.

What is the use of fractional derivatives?

Fractional derivatives have various applications in mathematics, physics, engineering, and other fields. They can be used to model non-integer order systems, describe the behavior of complex systems, and solve differential equations with non-integer orders.

How is a fractional derivative calculated?

A fractional derivative can be calculated using different methods, such as the Riemann-Liouville, Caputo, or Grunwald-Letnikov definitions. Each method has its own advantages and is used depending on the specific problem at hand.

Are there any real-world examples of fractional derivatives?

Yes, fractional derivatives have been used to model various phenomena in the real world. For example, they have been used to describe the behavior of viscoelastic materials, the spread of diseases, and the flow of fluids in porous media.

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