Acta Univ. Sapientiae, Mathematica, 7, 2 (25) 3 4 DOI:.55/ausm-25-9 The solutions of time and space conformable fractional heat equations with conformable Fourier transform Yücel Çenesiz Department of Mathematics, Faculty of Science, Selçuk University, Turkey email: ycenesiz@selcuk.edu.tr, ycenesiz@ymail.com Ali Kurt Department of Mathematics, Faculty of Science and Art, Mustafa Kemal University, Turkey email: alikurt@mku.edu.tr Abstract. In this paper our aim is to find the solutions of time and space fractional heat differential equations by using new definition of fractional derivative called conformable fractional derivative. Also based on conformable fractional derivative definition conformable Fourier Transform is defined. Fourier sine and Fourier cosine transform definitions are given and space fractional heat equation is solved by conformable Fourier transform. Introduction Fractional differential equations which are the generalization of differential equations are successful models of real life events and have many applications in various fields in science []-[8]. So the subject becomes very captivating. Hence, many researchers have been trying to form a new definition of fractional derivative. Most of these definitions include integral form for fractional derivatives. Two of these definitions which are most popular: 2 Mathematics Subject Classification: 26A33, 35R, 34A8 Key words and phrases: time fractional heat equation, space fractional heat equation, conformable fractional derivative, conformable Fourier transform 3
The solutions of time and space conformable fractional heat equations 3. Riemann-iouville definition: If n is a positive integer and [n, n), derivative of f is given by D a(f)(t) = t d n Γ(n ) dt n a f(x) dx. (t x) n+ 2. Caputo definition: If n is a positive integer and [n, n), derivative of f is given by D a(f)(t) = Γ(n ) t a f (n) (x) dx. (t x) n+ In [9, ] R. Khalil and et al. give a new definition of fractional derivative called conformable fractional derivative. Definition et f : [, ) R be a function. th order conformable fractional derivative of f is defined by T (f)(t) = lim ε f(t + εt ) f(t) ε for all t >, (, ). If fis -differentiable in some (, a), a >, and lim t + f() (t) exists, then define f () () = lim t + f() (t). This new definition satisfies the properties which are given in the following theorem [9, ]. Theorem et (, ] and f, g be differentiable at point t >. Then (a) T (cf + dg) = ct (f) + dt (g), for all a, b R. (b) T (t p ) = pt p for all p R. (c) T (λ) = for all constant functions f(t) = λ. (d) T (fg) = ft (g) + gt (f). ( ) (e) T f g = gt(g) ft(f). g 2
32 Y. Çenesiz, A. Kurt (f) If, in addition to f is differentiable, then T (f)(t) = t df dt. In Section 2, we will give the solution of fractional heat equation for < < with the help of conformable fractional derivative definition. In Section 3, we will give conformable Fourier transform, conformable Fourier sine and cosine transform definitions and solve the space fractional heat equation with this transform. 2 Time fractional heat equation General form for one dimension heat equation is u t = κ 2 u x 2. Heat equation has many fractional forms. In this paper we investigate the solution of time fractional heat differential equation: with conditions u t = u κ 2, < x <, t > x2 () u(, t) =, t (2) u(, t) =, t (3) u(x, ) = f(x), x (4) where the derivative is conformable fractional derivative and < <. Firstly we can mention conformable fractional linear differential equations with constant coefficients y t ± µ2 y =. (5) From formula (f) in Theorem we can obtain y dy = t t dt. (6) By substituting (6) in (5) it becomes following first order linear differential equation dy t dt ± µ2 y =. (7)
The solutions of time and space conformable fractional heat equations 33 One can easily see that the solution of equation (7) y = ce ±µ2 t. (8) Now we can use separation of variables method [] for solution of our time fractional heat equation (). et u = P(x)Q(t). Substituting this equation in Eq. (), we have from which we obtain d Q(t) dt P(x) = P(x) κd2 dx 2 Q(t) d Q(t) dt /κq(t) = d2 P(x) dx 2 /P(x) = ω. As a result: d Q(t) dt ωκq(t) = and d 2 P(x) dx 2 ωp(x) =. Now, we think about the equation d 2 P(x) dx 2 ωp(x) =. For this equation, there are three cases for values of ω to be evaluated. ω =, ω = µ 2, ω = µ 2. Conditions (2) and (3) give µ = nπ Equations (5) and (8) give, and P n(x) = a n sin nπx. (9) nπ Q n (t) = b n e ( ) 2 κ t. () Then, using the equations (9) and () the solution of the Cauchy problem which satisfies two boundary conditions obtained as u(x, t) = n= c n sin nπx e ( nπ ) 2 κ t. ()
34 Y. Çenesiz, A. Kurt With the help of condition (4) c n = 2 ( nπx ) f(x) sin dx. (2) Substituting (2) in () we find the solution as u(x, t) = n= sin nπx nπ e ( ) 2 κ t 2 f(x) sin 3 Conformable Fourier transform ( nπx ) dx. In [2] Abdeljawad gave the definition of conformable aplace transform and in [3] Negero made a study on application of Fourier transform to partial differential equations. Now in this section we define conformable Fourier transform, infinite and finite Fourier sine and cosine transform. We give some properties of this transforms. At the end we use finite Fourier sine transform to solve space fractional heat equation. Definition 2 et < and h(x) is real valued function defined on (, ). The conformable Fourier transform of h(x) which is denoted by F {h(t)} (w) is given by F {h(t)} (w) = H (w) = e iw t h(t) t dt. Theorem 2 et < and h(x) is differentiable real valued function defined on (, ). Then F {T (h)(t)} (w) = iwh (w). Proof. The proof followed by Theorem (f) and known integration by parts. emma et f : (, ) R be a function which satisfies F {h(t), w} = H (w) property. Then, } F {h(t)} (w) = F {h((t) ) (w) (3)
The solutions of time and space conformable fractional heat equations 35 where F {h(t)} (w) = e iwt h(t) dt. Proof. One can prove it easily by setting t = u. emma 2 F {h(t)} (w) Fourier transform is a linear operator. F {af + bg} = af {f} + bf {g}. Theorem 3 (Convolution Theorem). et g(t) and h(t) be arbitrary functions. Then F {g h} = F {g} F {h} where g h is the convolution of functions g(t) and h(t) defined as (g h)(t) = g(x)h(t x)dx = g(t x)h(x)dx. Proof. From emma, by using definition and changing the order of integration, we get } F {(g h)(t)} = F {(g h)((t) ), = g((x) )h(((t x)) )e iwt dxdt, = g((x) )h(((t x)) )e iwt dtdx. By making substitution t x = v, so t = v + x, F {(g h)(t)} = g((x) )h((v) )e iw(v+x) dvdx, = = F {g} F {h}. g((x) )e iwx dx h((v) )e iwv dv,
36 Y. Çenesiz, A. Kurt Conformable Fourier transform of partial derivatives emma 3 For given u(x, t) with < x < and t >, we have { i. F δ δt (u(x, t))} (w) = d dtu(w, t). ii. F { δ n δt n (u(x, t)) } (w) = dn dt n u(w, t), n =, 2, 3,... iii. F {T (u(x, t))} (w) = iw u(w, t). iv. F T... T (u(x, t)) }{{} (w) = (iw)n u(w, t), n =, 2, 3,... n times Fourier sine and cosine transform In this subsection we shall discuss the Fourier sine and cosine transforms and some of their properties. These transforms are convenient for problems over semi-infinite and some of finite intervals in a spatial variable in which the function or its derivative is prescribed on the boundary. Infinite Fourier sine and cosine transform Definition 3 (Fourier cosine transform). The Fourier cosine Transform of a function f : [, ] R which is denoted by F c (f(t)) is defined as F c {f(t)} = f(w) = F c (w) = ( ) 2 f(x) cos w x x dx. π Definition 4 (Fourier sine transform). The Fourier sine Transform of a function f : [, ] R is defined as emma 4 F s F s {f(t)} = f(w) = F s (w) = and F c are linear operators, i.e., ( ) 2 f(x) sin w x x dx. π F c {af + bg} = af c {f} + bf c {g}, F s {af + bg} = af s {f} + bf s {g}. Theorem 4 et f be a function defined for t > and f(t) as x. Then
The solutions of time and space conformable fractional heat equations 37. F c (T (f)(t)) = wf 2 s (f(t)) π f(). 2. F s (T (f)(t)) = wf c (f(t)). Proof. It can be easily proved by using Theorem (f) and integration by parts. Finite Fourier sine and cosine transform When the physical problem is defined on a finite domain, it is generally not suitable to use transformation with an infinite range of integration. In such cases usage of finite Fourier transform is very advantageous. Definition 5 The finite Fourier sine transform of f(t), < t < defined as ( ) nπt F s {f(t)} = F s (n) = f(t) sin t dt where < <. The inverse Fourier sine transform is defined as follows, f(x) = 2 n= ( ) nπt F s (n) sin. Definition 6 The finite Fourier cosine transform of f(t), < t < defined as ( ) nπt F c {f(t)} = F c (n) = f(t) cos t dt where < <. The inverse Fourier cosine transform is defined as follows, f(x) = F c () + 2 n= ( ) nπt F c (n) cos. In bounded domain, the Fourier sine and cosine transforms are useful to solve PDE s. Therefore we can give following calculations. { δ F } u s δx = nπ F c {u(x, t)},
38 Y. Çenesiz, A. Kurt F s { δ δ } u δx δx And then, = nπ F c = n2 π 2 2 2 { δ } u δx F s {u(x, t)} nπ [u(, t) cos nπ u(, t)]. (4) F { δ u c F { δ c δx δ u } δx = nπ F s {u(x, t)} [u(, t) u(, t) cos nπ], } [ δx = n 2 π 2 2 F c {u(x, t)} nπ δ u(,t) δx 2 δ u(,t) δx ] cos nπ. Now, let s apply this transform to solve space fractional heat equation, with the conditions, δu δt = δ δ u δx, < x <, t > (5) δx u(, t) = u(, t) = (6) u(x, ) = f(x) (7) where < <. When we apply the Fourier sine transform both sides of the equation, we have the following equality by using (4) and the conditions (6) d u(n, t) dt = n2 π 2 2 2 u(n, t). Solving the above differential equation gives us, u(n, t) = Ce n2 π 2 2 2 t. To evaluate C, we apply Fourier sine transform to the condition (7). At the end we have C as, Hence we get, ( ) nπx C = u(n, ) = f(x) sin x dx. u(n, t) = ( ) nπx f(x) sin x dx e n2 π 2 2 2 t.
The solutions of time and space conformable fractional heat equations 39 At the end applying inverse Fourier sine transform, the solution of Eq. (5) obtained as u(x, t) = 2 ( ) ( ) nπx f(x) sin x dx e n2 π 2 2 2 t nπx sin. n= 4 Conclusion In this paper we discuss about the solution of time and space fractional heat differential equations. Conformable fractional derivative definition is used for the solution time fractional heat equation. Conformable Fourier transform which will have very important role in fractional calculus like conformable aplace transform is defined and given an application for space fractional heat equation. We can say that this definition has many advantages in the solution procedure of fractional differential equations. Some comparisons with classical fractional differential equations are given by Khalil and Abdeljawad before. This paper can help to see the researchers that given definitions are very helpful under the suitable conditions. References [] K. Oldham, J. Spanier, The Fractional Calculus, Theory and Applications of Differentiation and Integration of Arbitrary Order, Academic Press, 974. [2] K. S. Miller, B. Ross, An Introduction to the Fractional Calculus and Fractional Differential Equations, A Wiley-Interscience Publication, 993. [3] I. Podlubny, Fractional Differential Equations, Academic Press, 999. [4] A. A. Kilbas, H. M. Srivastava, J. J. Trujillo, Theory and Applications of Fractional Differential Equations, Elsevier, 26. [5] N. Nyamoradi, Infinitely Many Solutions for a Class of Fractional Boundary Value Problems with Dirichlet Boundary Conditions, Mediterr. J. Math., (24), 75 87. [6] R. Garrappa, M. Popolizio, Exponential Quadrature Rules for inear Fractional Differential Equations, Mediterr. J. Math., 2 (25), 29 244.
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