ON SOME INTEGRODIFFERENTIAL EQUATIONS OF FRACTIONAL ORDERS

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Int. J. Contemp. Math. Sciences, Vol. 1, 26, no. 15, 719-726 ON SOME INTEGRODIFFERENTIAL EQUATIONS OF FRACTIONAL ORDERS Mahmoud M. El-Borai, Khairia El-Said El-Nadi and Eman G. El-Akabawy Faculty of Science, Alexandria University Alexandria, Egypt Abstract In this note the solutions of some integrodifferential equations with fractional orders in a Banach space are considered.conditions are given which ensure the existence of a resolvent operator for an integrodifferential equation in a Banach space. Keywords: Fractional integrodifferential equations - Semigroup - Resolvent operators. Mathematics Subject Classifications: 26A33, 45D5, 45N5 1.Introduction In this note we shall be concerned with the fractional integrodifferential equation of the form d α x(t) t Ax(t) = B(t s)x(s)ds + f(t), dt α t > (1.1) with the initial condition x() = x X. (1.2) where X is a Banach space, <α 1, A is a linear closed operator defined on a dense set D(A)in X into X, [B(t) : t T 1 ] is a family of linear closed

72 M. M. El-Borai, Kh. El-Said El-Nadi and E. G. El-Akabawy operator defined on a dense set in X into X with domain at least D(A) while the function f : R + X is absolutely continuous. Without loss of generality we can assume that x =. It is assumed also that A generates an analytic semigroup Q(t).This condition implies Q(t) K for t and AQ(t) K/t for t>, where. is the norm in X and K is a positive constant[1-6].it is also assumed that x D(A) and B(t)x is strongly continuously differentiable on [,T] for x D(A). It is further assumed that [T (t)] t defined by T(t)f(s)= f(t+s) is a C semigroup on ℵ with generator D s on domain D(D s ) where ℵ is a subspace of the set of bounded uniformly continuous functions on R + into X. Let us suppose that B(t),B (t) :Y D(D s ) where Y is the Banach space formed from D(A),the domain of A, endowed with the graph norm y Y = Ay + y.as A and B(t) are closed operators it follows that A and B(t) are in the set of bounded operators from Y to X B(Y,X) for <t T assume further that B(t) is continuous on <t T into B(Y,X).It is also supposed that D s B(t),D s B (t) is continuous on [, ) into B(Y,ℵ)[7].The theory of fractional calculus is essentially based on the integral convolution betweenf and the following generalized function,introduced by Gelfand and Shilov, φ λ (t)=t λ +/ Γ(λ), where λ is a complex number,t λ + =tλ θ(t),θ(t) being the Heaviside step function,and Γ(λ) is the gamma function. Following Gelfand and Shilov we can define the integral of order α>by I α f (t) = 1 (t θ) α 1 f (θ)dθ. (1.3) Γ(α) If <α 1, we can define the derivative of order α by d α f (t) dt α = 1 d Γ(1 α) dt (see [8-1]).If n 1 <α<n,then it easy to see that d α f (t) dt α = 1 t Γ(n α) f (n) (θ) (t θ) α+1 n dθ + n f (θ) dθ, (1.4) (t θ) α k= f (k) ( + )φ k α+1 (t), (1.5)

ON SOME INTEGRODIFFERENTIAL EQUATIONS 721 where d α f (t) dt α (comp[11-13]) = dn 1 dt n In α f (t) = d n 1 Γ(n α) dt n f (θ) dθ, (1.6) (t θ) α+1 n We shall first consider the fractional evolution equation of the form d x(t) t dt (dα Ax(t)) = B dt α 1 x(t)+ B 2 (t s)x(s)ds + f(t) (1.7). with the initial conditions dx() x() =, =. (1.8) dt then we obtain the solution of the problem (1.1),(1.2).Finally an application is considered 2.Existence of solutions Theorem 2.1 Assume that B 1 and B 2 (t) are closed linear operators defined on dense sets in X into X with domains at least D(A),and B 2 (t)x is strongly continuous in t on [,T] for x D(A).It is also assumed that the domain of B 2 (t) does not depend on t.if B 1,B 2 (t) :Y D(D s ) and f 1 : R + X is continuous,then the problem (1.7),(1.8) has a unique solution η x(t) =α θζ α (θ)(t η) α 1 Q((t η) α θ)r(η v)f(v)dθdvdη. (2.1) Proof: First we assume that d α x(t) dt α Ax(t) =U(t). (2.2)

722 M. M. El-Borai, Kh. El-Said El-Nadi and E. G. El-Akabawy Hence formally, from [14]: x(t) =α θζ α (θ)(t η) α 1 Q((t η) α θ)u(η)dθdη, (2.3) where ζ α (θ) is a probability density function defined on (, ).From (1.7), (1.8), (2.2) and (2.3) we get du(t) dt = α + α φ θζ α (θ)(t η) α 1 B 1 Q((t η) α θ)u(η)dθdη θζ α (θ)b 2 (t φ)(φ η) α 1 Q((φ η) α θ)u(η)dθdηdφ + f 1 (t), (2.4) We rewrite equation (2.4) as U() =. (2.5) du(t) dt = = B 3 (t η)u(η)dη + B 4 (t η)u(η)dη + f 1 (t) B 5 (t η)u(η)dη + f 1 (t), (2.6) where B 3 (t η) =α θζ α (θ)(t η) α 1 B 1 Q((t η) α θ)dθ, B 4 (t η) =α η θζ α (θ)b 2 (t φ)(φ η) α 1 Q((φ η) α θ)dθdφ, B 5 (t η) =B 3 (t η)+b 4 (t η). (2.7) Equation(2.6)has a unique resolvent operator R(t) which satisfies R(t η) = B 5 (t r)r(r η)dr. (2.8) t η Then equations (2.5),(2.6) has a unique solution U(t) = R(t η)f(η)dη. (2.9) By differentiating (2.9) and using (2.8).Hence by Fubini s theorem we obtain (2.4). Then x(t) =α η θζ α (θ)(t η) α 1 Q((t η) α θ)r(η v)f(v)dθdvdη.

ON SOME INTEGRODIFFERENTIAL EQUATIONS 723 Theorem 2.2 The problem (1.1),(1.2) has a unique solution x(t) =α d dt η θζ α (θ)(t η) α 1 Q((t η) α θ)r 1 (η v)f(v)dθdvdη. (2.1) Proof: Let v(t) = x(θ)dθ. We can rewrite equation (1.1),(1.2) as d v t dt (dα dt Av(t)) = B(t s) dv ds + f(t) α ds = B()v(t)+ B (t s)v(s)ds + f(t), (2.11) dv() dt By using the previous theorem,we get v(t) =α η where R 1 (t η) t = α + α =. (2.12) θζ α (θ)(t η) α 1 Q((t η) α θ)r 1 (η v)f(v)dθdvdη, (2.13) η φ Hence the required result. η η θζ α (θ)b()(t r) α 1 Q((t r) α θ)dθdr θζ α (θ)b (t φ)(φ r) α 1 Q((φ r) α θ)dθdφdr. 3.Application As an application we consider the following equation: α u(x, t) a t α q (x)d q u(x, t) = b q (x, t s)d q u(x, s)ds+f(x, t),t>o q 2m q k (3.1)

724 M. M. El-Borai, Kh. El-Said El-Nadi and E. G. El-Akabawy with the initial condition u(x, ) = u (x). (3.2) where x = (x 1,..., x n ) S,S is a bounded domain in the n- dimensional Euclidean space R n with smooth boundary S,let L 2 (S) be the set of all square integrable functions on S.Denote by C m (S) the set of all continuous functions defined on S,which have continuous partial derivatives of order less than or equal to m,and by C m(s) we denote the set of all functions f Cm (S) with compact support. Let H m (S) be the completion of the space C m (S) with respect to the norm f m, f m =[ [D q f(x)] 2 dx] 1/2. q m S By H m (S) we denote the completion of the space C m (S) with respect to the norm f m. Let A and B be the differential operators defined by A = a q (x)d q, q 2m B = q k b q (x, t)d q. It is assumed that: (1) The domain of definition D(A) of A is defined by D(A) =H 2m (S) H m. (2) ( 1) m 1 q =2m a q (x)ξ q δ ξ 2m, for all x S S and for all ξ = (ξ 1,..., ξ n ) (,...),where δ is a positive constant independent of x and ξ, ( ξ 2 = ξ1 2 +... + ξ2 n, ξq = ξ q 1 1...ξn qn). (3) The coefficients a q are continuous on S,for all q 2m and the coefficients on S [,T],for all q k,where T>. (4) f is continuous on S [,T]. Under these conditions the differential operator A generates an analytic semigroup Q(t),where: Q(t)u = G(x ξ,t)u (ξ)dξ, R n

ON SOME INTEGRODIFFERENTIAL EQUATIONS 725 where dξ = dξ 1...dξ n and G is the fundamental solution of the Cauchy problem: u(x, t) t = q 2m u(x, ) = u (x) a q (x)d q u(x, t), Now as an application of theorem 2.2, we can prove that the Cauchy problem (3.1),(3.2) has a unique solution. References [1] A.Friedman and M.shinbrot, Volterra integral equations in a Banach space. Trans.Amer.Math.Soc 126 (1967),131-179. [2] R.C.Grimmer, Resolvent operators for integral equations in a Banach space. Trans.Amer.Math.Soc. 273 (1982),no1,33-349. [3] Hille E,Philips RS In:Functional analysis and semigroup.ameer.math.soc colloquium publication Vol.31 providence(ri):amer Math Soc(1957). [4] Abujabal HAS,EL-Borai MM.On the Cauchy problem for some abstract nonlinear differential equation.korean J comput Appl Math 1996,3(7). [5] El-Borai MM,Evolution equations without semigroup. Applied mathematics and computation 149 (24) 815-821. [6] EL-Borai MM, Semigroup and some nonlinear fractional differential equations. Applied Mathematics and Computation 149(24)823-831. [7] K.Balachandran and J.Y.Park, Existence of solutions and controllability of nonlinear integrodifferential systems in Banach spaces.mathematical Problems in Engineering2(23)65-79. [8] Schneider WR,Wayes W, Fractional diffusion and wave equation.j Math Phys(1989)3 [9] Wayes W, The fractional diffusion equation.j Math Phys(1986)27. [1] EL-Borai MM, The fundamental solutions for fractional evolution equations of parabolic type,applied Mathematics and Stochastic Analysis 3(24)197-211.

726 M. M. El-Borai, Kh. El-Said El-Nadi and E. G. El-Akabawy [11] Gorenflo R,Mainardi F, Fractional calculus and stable probability distributions.arch Mach 5(1995). [12] Mainradi F, Fractional relaxation-oscillation and fractional diffusion-wave phenomena chaos,solitons Fractals 7(1996). [13] J.P.Dauer and K.Balachandran, Existence of solutions for an integrodifferential equations with nonlocal condition in Banach spaces,libertas Math 16(1996),133-143. [14] EL-Borai MM, Some probability densities and fundamental solutions of fractional evolution equation, Chaos Solitons Fractals 14(22) 433-44. E-mail addresses: m m elborai@yahoo.com. khairia el said@hotmail.com. e elakabawy@yahoo.com. Received: February 18, 26

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