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Applied Mathematical Sciences, Vol. 4, 2010, no. 21, 1021 - 1032
Applications of Fractional Calculus
Mehdi Dalir
Department of Mathematics
Faculty of Sciences
Islamic Azad University of Varamin(Pishva)
Varamin-Tehran-Iran
Majid Bashour
Department of Mathematics
Faculty of Sciences
Islamic Azad University of Varamin(Pishva)
Varamin-Tehran-Iran
majidbashour@yahoo.com
Abstract
Different denitions of fractional derivatives and fractional Integrals
(Differintegrals) are considered. By means of them explicit formula
and graphs of some special functions are derived. Also we reviw some
applications of the theory of fractional calculus.
Mathematics Subject Classication: 26A33
Keywords: fractional derivative, fractional Integral, differintegrals
1 Introduction
Fractional calculus is a eld of mathematics study that qrows out of the tra-
ditional denitions of calculus integral and derivative operators in much the
samewayfractionalexponentsisanoutgrowthofexponentswithintegervalue.
The concept of fractional calculus( fractional derivatives and fractional in-
tegral) is not new. In 1695 LHospital asked the question as to the meaning
of dny/dxn if n =1/2; that is what if n is fractional?. Leibniz replied that
1/2 √
d x will be equal to x dx : x.
It is generally known that integer-order derivatives and integrals have clear
physical and geometric interpretations. However, in case of fractional-order
integration and differentiation, which represent a rapidly qrowing eld both in
1022 M. Dalir and M. Bashour
theoryandinapplicationstorealworldproblems, itisnotso. Sincetheappear-
ance of the idea of differentiation and integration of arbitrary (not necessary
integer) order there was not any acceptable geometric and physical interpre-
tation of these operations for more than 300 year. In [11], it is shown that
geometric interpretation of fractional integration is Shadows on the walls
and its Physical interpretation is Shadows of the past.
In the last years has found use in studies of viscoelastic materials, as well as
in manyeldsofscienceandengineeringincluding uidow, rheology, diffusive
transport, electerical networks, electromagnetic theory and probability.
In this paper we consider different denitions of fractional derivatives and
integrals (differintegrals). For some elementary functions, explicit formula of
fractional drevative and integral are presented. Also we present some applica-
tions of fractional calculus in science and engineering.
2 Different Denitions
In this section we consider different denitions of fractional calculus.
1. L. Euler(1730):
Euler generalized the formula
n m
d x mn
n =m(m1)···(mn+1)x
dx
by using of the following property of Gamma function,
(m+1)=m(m1)···(mn+1)(mn+1)
to obtain
n m
d x (m+1) mn
n = x .
dx (mn+1)
Gammafunction is dened as follows.
∞ t z1
(z)= e t dt, Re(z) > 0
0
2. J. B. J. Fourier (1820 - 1822):
By means of integral representation
Applications of fractional calculus 1023
f(x)= 1 ∞ f(z)dz ∞ cos(pxpz)dp
2π ∞ ∞
he wrote
dnf(x) = 1 ∞ f(z)dz ∞ cos(pxpz+nπ)dp,
n
dx 2π ∞ ∞ 2
3. N. H. Abel (1823- 1826):
Abel considered the integral representation x s′(η)dη = ψ(x) for ar-
(xη)α
0
bitrary α and then wrote
s(x)= 1 dαψ(x).
α
(1α) dx
4. J. Lioville (1832 - 1855):
I. In his rst denition, according to exponential representation of a
m ax
∞ a x d e
function f(x)= cne n , he generalized the formula n =
n=0 dx
m ax
a e as
ν ∞
d f(x) ν ax
= cna e n
ν n
dx n=0
II. Second type of his denition was Fractional Integral
µ µ 1 ∞ µ1
Φ(x)dx = µ Φ(x+α)α dα
(1) (µ) 0
µ µ 1 ∞ µ1
Φ(x)dx = (µ) 0 Φ(xα)α dα
By substituting of τ = x +α and τ = xα in the above formulas
respectively, he obtained
µ µ 1 ∞ µ1
Φ(x)dx = µ (τ x) Φ(τ)dτ
(1) (µ) x
µ µ 1 x µ1
Φ(x)dx = (µ) ∞(xτ) Φ(τ)dτ.
1024 M. Dalir and M. Bashour
III. Third denition, includes Fractional derivative,
µ µ
d F(x) (1) µ µ(µ1)
µ = µ F(x) F(x+h)++ F(x+2h)···
dx h 1 1·2
dµF(x) 1 µ µ(µ1)
µ = µ F(x) F(xh)++ F(x2h)··· .
dx h 1 1·2
5. G. F. B. Riemann (1847 - 1876):
His denition of Fractional Integral is
ν 1 x ν1
D f(x)=(ν) c (xt) f(t)dt +ψ(t)
6. N. Ya. Sonin (1869), A. V. Letnikov (1872), H. Laurent (1884),
N. Nekrasove (1888), K. Nishimoto (1987-):
They considered to the Cauchy Integral formula
f(n)(z)= n! f(t) dt
2πi (t z)n+1
c
and substituted n by ν to obtain
Dνf(z)=(ν+1) x+ f(t) dt.
2πi (t z)ν+1
c
7. Riemann-Liouvill denition:
The popular denition of fractional calculus is this which shows joining
of two previous denitions.
1 d n t f(τ)dτ
Dαf(t)=
a t (nα) dt (t τ)αn+1
a
(n1≤α
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