Generalization of derivative to fractals
In applied mathematics and mathematical analysis , the fractal derivative or Hausdorff derivative is a non-Newtonian generalization of the derivative dealing with the measurement of fractals , defined in fractal geometry. Fractal derivatives were created for the study of anomalous diffusion, by which traditional approaches fail to factor in the fractal nature of the media. A fractal measure t is scaled according to tα . Such a derivative is local, in contrast to the similarly applied fractional derivative . Fractal calculus is formulated as a generalization of standard calculus.[ 1]
Physical background [ edit ] Porous media , aquifers , turbulence , and other media usually exhibit fractal properties. Classical diffusion or dispersion laws based on random walks in free space (essentially the same result variously known as Fick's laws of diffusion , Darcy's law , and Fourier's law ) are not applicable to fractal media. To address this, concepts such as distance and velocity must be redefined for fractal media; in particular, scales for space and time are to be transformed according to (xβ , tα ). Elementary physical concepts such as velocity are redefined as follows for fractal spacetime (xβ , tα ):[ 2]
v ′ = d x ′ d t ′ = d x β d t α , α , β > 0 {\displaystyle v'={\frac {dx'}{dt'}}={\frac {dx^{\beta }}{dt^{\alpha }}}\,,\quad \alpha ,\beta >0} , where Sα,β represents the fractal spacetime with scaling indices α and β . The traditional definition of velocity makes no sense in the non-differentiable fractal spacetime.[ 2]
Based on above discussion, the concept of the fractal derivative of a function f (t ) with respect to a fractal measure t has been introduced as follows:[ 3]
∂ f ( t ) ∂ t α = lim t 1 → t f ( t 1 ) − f ( t ) t 1 α − t α , α > 0 {\displaystyle {\frac {\partial f(t)}{\partial t^{\alpha }}}=\lim _{t_{1}\rightarrow t}{\frac {f(t_{1})-f(t)}{t_{1}^{\alpha }-t^{\alpha }}}\,,\quad \alpha >0} , A more general definition is given by[ 3]
∂ β f ( t ) ∂ t α = lim t 1 → t f β ( t 1 ) − f β ( t ) t 1 α − t α , α > 0 , β > 0 {\displaystyle {\frac {\partial ^{\beta }f(t)}{\partial t^{\alpha }}}=\lim _{t_{1}\rightarrow t}{\frac {f^{\beta }(t_{1})-f^{\beta }(t)}{t_{1}^{\alpha }-t^{\alpha }}}\,,\quad \alpha >0,\beta >0} . For a function y(t) on F α {\displaystyle F^{\alpha }} -perfect fractal set F the fractal derivative or F α {\displaystyle F^{\alpha }} -derivative of y(t) at t is defined by
D F α y ( t ) = { F − lim x → t y ( x ) − y ( t ) S F α ( x ) − S F α ( t ) , if t ∈ F ; 0 , otherwise . {\displaystyle D_{F}^{\alpha }y(t)=\left\{{\begin{array}{ll}{\underset {x\rightarrow t}{F_{-}\lim }}~{\frac {y(x)-y(t)}{S_{F}^{\alpha }(x)-S_{F}^{\alpha }(t)}},&{\text{if}}~t\in F;\\0,&{\text{otherwise}}.\end{array}}\right.} . The derivatives of a function f can be defined in terms of the coefficients ak in the Taylor series expansion:
f ( x ) = ∑ k = 1 ∞ a k ⋅ ( x − x 0 ) k = ∑ k = 1 ∞ 1 k ! d k f d x k ( x 0 ) ⋅ ( x − x 0 ) k = f ( x 0 ) + f ′ ( x 0 ) ⋅ ( x − x 0 ) + o ( x − x 0 ) {\displaystyle f(x)=\sum _{k=1}^{\infty }a_{k}\cdot (x-x_{0})^{k}=\sum _{k=1}^{\infty }{1 \over k!}{d^{k}f \over dx^{k}}(x_{0})\cdot (x-x_{0})^{k}=f(x_{0})+f'(x_{0})\cdot (x-x_{0})+o(x-x_{0})}
From this approach one can directly obtain:
f ′ ( x 0 ) = f ( x ) − f ( x 0 ) − o ( x − x 0 ) x − x 0 = lim x → x 0 f ( x ) − f ( x 0 ) x − x 0 {\displaystyle f'(x_{0})={f(x)-f(x_{0})-o(x-x_{0}) \over x-x_{0}}=\lim _{x\to x_{0}}{f(x)-f(x_{0}) \over x-x_{0}}}
This can be generalized approximating f with functions (xα -(x0 )α )k :
f ( x ) = ∑ k = 1 ∞ b k ⋅ ( x α − x 0 α ) k = f ( x 0 ) + b 1 ⋅ ( x α − x 0 α ) + o ( x α − x 0 α ) {\displaystyle f(x)=\sum _{k=1}^{\infty }b_{k}\cdot (x^{\alpha }-x_{0}^{\alpha })^{k}=f(x_{0})+b_{1}\cdot (x^{\alpha }-x_{0}^{\alpha })+o(x^{\alpha }-x_{0}^{\alpha })}
Note that the lowest order coefficient still has to be b0 =f(x0 ), since it's still the constant approximation of the function f at x0 .
Again one can directly obtain:
b 1 = lim x → x 0 f ( x ) − f ( x 0 ) x α − x 0 α = d e f d f d x α ( x 0 ) {\displaystyle b_{1}=\lim _{x\to x_{0}}{f(x)-f(x_{0}) \over x^{\alpha }-x_{0}^{\alpha }}{\overset {\underset {\mathrm {def} }{}}{=}}{df \over dx^{\alpha }}(x_{0})}
The Fractal Maclaurin series of f(t) with fractal support F is as follows:
f ( t ) = ∑ m = 0 ∞ ( D F α ) m f ( t ) | t = 0 m ! ( S F α ( t ) ) m {\displaystyle f(t)=\sum _{m=0}^{\infty }{\frac {(D_{F}^{\alpha })^{m}f(t)|_{t=0}}{m!}}(S_{F}^{\alpha }(t))^{m}}
Expansion coefficients [ edit ] Just like in the Taylor series expansion, the coefficients bk can be expressed in terms of the fractal derivatives of order k of f:
b k = 1 k ! ( d d x α ) k f ( x = x 0 ) {\displaystyle b_{k}={1 \over k!}{\biggl (}{d \over dx^{\alpha }}{\biggr )}^{k}f(x=x_{0})}
Proof idea: Assuming
( d d x α ) k f ( x = x 0 ) {\textstyle ({d \over dx^{\alpha }})^{k}f(x=x_{0})}
exists, bk can be written as
b k = a k ⋅ ( d d x α ) k f ( x = x 0 ) {\textstyle b_{k}=a_{k}\cdot ({d \over dx^{\alpha }})^{k}f(x=x_{0})}
One can now use
f ( x ) = ( x α − x 0 α ) n ⇒ ( d d x α ) k f ( x = x 0 ) = n ! δ n k {\textstyle f(x)=(x^{\alpha }-x_{0}^{\alpha })^{n}\Rightarrow ({d \over dx^{\alpha }})^{k}f(x=x_{0})=n!\delta _{n}^{k}}
and since
b n = ! 1 ⇒ a n = 1 n ! {\textstyle b_{n}{\overset {\underset {\mathrm {!} }{}}{=}}1\Rightarrow a_{n}={1 \over n!}}
If for a given function f both the derivative Df and the fractal derivative Dα f exist, one can find an analog to the chain rule:
d f d x α = d f d x d x d x α = 1 α x 1 − α d f d x {\displaystyle {df \over dx^{\alpha }}={df \over dx}{dx \over dx^{\alpha }}={1 \over \alpha }x^{1-\alpha }{df \over dx}}
The last step is motivated by the implicit function theorem which, under appropriate conditions, gives us
d x d x α = ( d x α d x ) − 1 {\displaystyle {\frac {dx}{dx^{\alpha }}}=({\frac {dx^{\alpha }}{dx}})^{-1}}
Similarly for the more general definition:
d β f d α x = d ( f β ) d α x = 1 α x 1 − α β f β − 1 ( x ) f ′ ( x ) {\displaystyle {d^{\beta }f \over d^{\alpha }x}={d(f^{\beta }) \over d^{\alpha }x}={1 \over \alpha }x^{1-\alpha }\beta f^{\beta -1}(x)f'(x)}
Fractal derivative for function f (t ) = t , with derivative order is α ∈ (0,1] Application in anomalous diffusion [ edit ] As an alternative modeling approach to the classical Fick's second law, the fractal derivative is used to derive a linear anomalous transport-diffusion equation underlying anomalous diffusion process,[ 3]
d u ( x , t ) d t α = D ∂ ∂ x β ( ∂ u ( x , t ) ∂ x β ) , ( 1 ) {\displaystyle {\frac {du(x,t)}{dt^{\alpha }}}=D{\frac {\partial }{\partial x^{\beta }}}\left({\frac {\partial u(x,t)}{\partial x^{\beta }}}\right),\quad (1)} u ( x , 0 ) = δ ( x ) {\displaystyle u(x,0)=\delta (x)} where 0 < α < 2, 0 < β < 1, x ∈ R {\displaystyle x\in \mathbb {R} } , and δ (x ) is the Dirac delta function .
To obtain the fundamental solution , we apply the transformation of variables
t ′ = t α , x ′ = x β . {\displaystyle t'=t^{\alpha }\,,\quad x'=x^{\beta }.} then the equation (1) becomes the normal diffusion form equation, the solution of (1) has the stretched Gaussian kernel :[ 3]
u ( x , t ) = 1 2 π t α e − x 2 β 4 t α {\displaystyle u(x,t)={\frac {1}{2{\sqrt {\pi t^{\alpha }}}}}e^{-{\frac {x^{2\beta }}{4t^{\alpha }}}}} The mean squared displacement of above fractal derivative diffusion equation has the asymptote :[ 3]
⟨ x 2 ( t ) ⟩ ∝ t ( 3 α − α β ) / 2 β . {\displaystyle \left\langle x^{2}(t)\right\rangle \propto t^{(3\alpha -\alpha \beta )/2\beta }.} Fractal-fractional calculus [ edit ] The fractal derivative is connected to the classical derivative if the first derivative exists. In this case,
∂ f ( t ) ∂ t α = lim t 1 → t f ( t 1 ) − f ( t ) t 1 α − t α = d f ( t ) d t 1 α t α − 1 , α > 0 {\displaystyle {\frac {\partial f(t)}{\partial t^{\alpha }}}=\lim _{t_{1}\rightarrow t}{\frac {f(t_{1})-f(t)}{t_{1}^{\alpha }-t^{\alpha }}}\ ={\frac {df(t)}{dt}}{\frac {1}{\alpha t^{\alpha -1}}},\quad \alpha >0} . However, due to the differentiability property of an integral, fractional derivatives are differentiable, thus the following new concept was introduced by Prof Abdon Atangana from South Africa.
The following differential operators were introduced and applied very recently.[ 4] Supposing that y(t) be continuous and fractal differentiable on (a, b) with order β , several definitions of a fractal–fractional derivative of y(t) hold with order α in the Riemann–Liouville sense:[ 4]
Having power law type kernel: F F P D 0 , t α , β ( y ( t ) ) = 1 Γ ( m − α ) d d t β ∫ 0 t ( t − s ) m − α − 1 y ( s ) d s {\displaystyle ^{FFP}D_{0,t}^{\alpha ,\beta }{\Big (}y(t){\Big )}={\dfrac {1}{\Gamma (m-\alpha )}}{\dfrac {d}{dt^{\beta }}}\int _{0}^{t}(t-s)^{m-\alpha -1}y(s)ds}
Having exponentially decaying type kernel: F F E D 0 , t α , β ( y ( t ) ) = M ( α ) 1 − α d d t β ∫ 0 t exp ( − α 1 − α ( t − s ) ) y ( s ) d s {\displaystyle ^{FFE}D_{0,t}^{\alpha ,\beta }{\Big (}y(t){\Big )}={\dfrac {M(\alpha )}{1-\alpha }}{\dfrac {d}{dt^{\beta }}}\int _{0}^{t}\exp {\Big (}-{\dfrac {\alpha }{1-\alpha }}(t-s){\Big )}y(s)ds} ,
Having generalized Mittag-Leffler type kernel: a F F M D t α f ( t ) = A B ( α ) 1 − α d d t β ∫ a t f ( τ ) E α ( − α ( t − τ ) α 1 − α ) d τ . {\displaystyle {}_{a}^{FFM}D_{t}^{\alpha }f(t)={\frac {AB(\alpha )}{1-\alpha }}{\frac {d}{dt^{\beta }}}\int _{a}^{t}f(\tau )E_{\alpha }\left(-\alpha {\frac {\left(t-\tau \right)^{\alpha }}{1-\alpha }}\right)\,d\tau \,.}
The above differential operators each have an associated fractal-fractional integral operator, as follows:[ 4]
F F P J 0 , t α , β ( y ( t ) ) = β Γ ( α ) ∫ 0 t ( t − s ) α − 1 s β − 1 y ( s ) d s {\displaystyle ^{FFP}J_{0,t}^{\alpha ,\beta }{\Big (}y(t){\Big )}={\dfrac {\beta }{\Gamma (\alpha )}}\int _{0}^{t}(t-s)^{\alpha -1}s^{\beta -1}y(s)ds}
Exponentially decaying type kernel: F F E J 0 , t α , β ( y ( t ) ) = α β M ( α ) ∫ 0 t s β − 1 y ( s ) d s + β ( 1 − α ) t β − 1 y ( t ) M ( α ) {\displaystyle ^{FFE}J_{0,t}^{\alpha ,\beta }{\Big (}y(t){\Big )}={\dfrac {\alpha \beta }{M(\alpha )}}\int _{0}^{t}s^{\beta -1}y(s)ds+{\dfrac {\beta (1-\alpha )t^{\beta -1}y(t)}{M(\alpha )}}} .
Generalized Mittag-Leffler type kernel: F F M J 0 , t α , β ( y ( t ) ) = α β A B ( α ) ∫ 0 t s β − 1 y ( s ) ( t − s ) α − 1 d s + β ( 1 − α ) t β − 1 y ( t ) A B ( α ) {\displaystyle ^{FFM}J_{0,t}^{\alpha ,\beta }{\Big (}y(t){\Big )}={\dfrac {\alpha \beta }{AB(\alpha )}}\int _{0}^{t}s^{\beta -1}y(s)(t-s)^{\alpha -1}ds+{\dfrac {\beta (1-\alpha )t^{\beta -1}y(t)}{AB(\alpha )}}} .
FFM refers to fractal-fractional with the generalized Mittag-Leffler kernel.
Fractal non-local calculus [ edit ] Fractal analogue of the right-sided Riemann-Liouville fractional integral of order β ∈ R {\displaystyle \beta \in \mathbb {R} } of f is defined by:[ 1] x I b β f ( x ) = 1 Γ ( β ) ∫ x b f ( t ) ( S F α ( t ) − S F α ( x ) ) 1 − β d F α t {\displaystyle {x}{\mathcal {I}}_{b}^{\beta }f(x)={\frac {1}{\Gamma (\beta )}}\int _{x}^{b}{\frac {f(t)}{(S_{F}^{\alpha }(t)-S_{F}^{\alpha }(x))^{1-\beta }}}d_{F}^{\alpha }t} .
Fractal analogue of the left-sided Riemann-Liouville fractional integral of order β ∈ R {\displaystyle \beta \in \mathbb {R} } of f is defined by: a I x β f ( x ) = 1 Γ ( β ) ∫ a x f ( t ) ( S F α ( x ) − S F α ( t ) ) 1 − β d F α t . {\displaystyle {a}{\mathcal {I}}_{x}^{\beta }f(x)={\frac {1}{\Gamma (\beta )}}\int _{a}^{x}{\frac {f(t)}{(S_{F}^{\alpha }(x)-S_{F}^{\alpha }(t))^{1-\beta }}}d_{F}^{\alpha }t.}
Fractal analogue of the right-sided Riemann-Liouville fractional derivative of order β ∈ R {\displaystyle \beta \in \mathbb {R} } of f is defined by: x D b β f ( x ) = 1 Γ ( n − β ) ( − D F α ) n ∫ x b f ( t ) ( S F α ( t ) − S F α ( x ) ) − n + β + 1 d F α t {\displaystyle {x}{\mathcal {D}}_{b}^{\beta }f(x)={\frac {1}{\Gamma (n-\beta )}}(-D_{F}^{\alpha })^{n}\int _{x}^{b}{\frac {f(t)}{(S_{F}^{\alpha }(t)-S_{F}^{\alpha }(x))^{-n+\beta +1}}}d_{F}^{\alpha }t}
Fractal analogue of the left-sided Riemann-Liouville fractional derivative of order β ∈ R {\displaystyle \beta \in \mathbb {R} } of f is defined by: a D x β f ( x ) = 1 Γ ( n − β ) ( D F α ) n ∫ a x f ( t ) ( S F α ( x ) − S F α ( t ) ) − n + β + 1 d F α t {\displaystyle {a}{\mathcal {D}}_{x}^{\beta }f(x)={\frac {1}{\Gamma (n-\beta )}}(D_{F}^{\alpha })^{n}\int _{a}^{x}{\frac {f(t)}{(S_{F}^{\alpha }(x)-S_{F}^{\alpha }(t))^{-n+\beta +1}}}d_{F}^{\alpha }t}
Fractal analogue of the right-sided Caputo fractional derivative of order β ∈ R {\displaystyle \beta \in \mathbb {R} } of f is defined by: x C D b β f ( x ) = 1 Γ ( n − β ) ∫ x b ( S F α ( t ) − S F α ( x ) ) n − β − 1 ( − D F α ) n f ( t ) d F α t {\displaystyle {x}^{C}{\mathcal {D}}_{b}^{\beta }f(x)={\frac {1}{\Gamma (n-\beta )}}\int _{x}^{b}(S_{F}^{\alpha }(t)-S_{F}^{\alpha }(x))^{n-\beta -1}(-D_{F}^{\alpha })^{n}f(t)d_{F}^{\alpha }t}
Fractal analogue of the left-sided Caputo fractional derivative of order β ∈ R {\displaystyle \beta \in \mathbb {R} } of f is defined by: a C D x β f ( x ) = 1 Γ ( n − β ) ∫ a x ( S F α ( x ) − S F α ( t ) ) n − β − 1 ( D F α ) n f ( t ) d F α t {\displaystyle {a}^{C}{\mathcal {D}}_{x}^{\beta }f(x)={\frac {1}{\Gamma (n-\beta )}}\int _{a}^{x}(S_{F}^{\alpha }(x)-S_{F}^{\alpha }(t))^{n-\beta -1}(D_{F}^{\alpha })^{n}f(t)d_{F}^{\alpha }t}
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