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Recommended by Paul Eloe

Department of Mathematics and Computer Science, Cankaya University, Eskisehir Yolu 29 km, 06810 Ankara, Turkey

Received 16 April 2012; Revised 4 June 2012; Accepted 5 June 2012

This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

1. Introduction

The fractional calculus, which is as old as the usual calculus, deals with the generalization of the integration and differentiation of integer order to arbitrary order. It has recently received a lot of attention because of its interesting applications in various fields of science, such as, viscoelasticity, diffusion, neurology, control theory, and statistics, see [ 1- 6].

The analogous theory for discrete fractional calculus was initiated by Miller and Ross [ 7], where basic approaches, definitions, and properties of the theory of fractional sums and differences were reported. Recently, a series of papers continuing this research has appeared. We refer the reader to the papers [ 8- 12] and the references cited therein.

In the early 1990's, Watugala [ 13, 14] introduced the Sumudu transform and applied it to solve ordinary differential equations. The fundamental properties of this transform, which are thought to be an alternative to the Laplace transform were then established in many articles [ 15- 19].

The Sumudu transform is defined over the set of functions [figure omitted; refer to PDF] by [figure omitted; refer to PDF]

Although the Sumudu transform of a function has a deep connection to its Laplace transform, the main advantage of the Sumudu transform is the fact that it may be used to solve problems without resorting to a new frequency domain because it preserves scales and unit properties. By these properties, the Sumudu transform may be used to solve intricate problems in engineering and applied sciences that can hardly be solved when the Laplace transform is used. Moreover, some properties of the Sumudu transform make it more advantageous than the Laplace transform. Some of these properties are

(i) The Sumudu transform of a Heaviside step function is also a Heaviside step function in the transformed domain.

(ii) ... { ^{t n} } (u ) =n ! ^{u n} .

(iii): _{lim u [arrow right] - τ 1} F (u ) = _{lim t [arrow right] - ∞} f (t ) .

(iv) _{lim u [arrow right] τ 2} F (u ) = _{lim t [arrow right] ∞} f (t ) .

(v) _{lim t [arrow right] ^{0 - or +}} f (t ) = _{lim u [arrow right] ^{0 - or +}} F (u ) .

(vi) For any real or complex number c , ... {f (ct ) } (u ) =F (cu ) .

In particular, since constants are fixed by the Sumudu transform, choosing c =0 , it gives F (0 ) =f (0 ) .

In dealing with physical applications, this aspect becomes a major advantage, especially in instances where keeping track of units, and dimensional factor groups of constants, is relevant. This means that in problem solving, u and G ( u ) can be treated as replicas of t and f ( t ), respectively [ 20].

Recently, an application of the Sumudu and Double Sumudu transforms to Caputo-fractional differential equations is given in [ 21]. In [ 22], the authors applied the Sumudu transform to fractional differential equations.

Starting with a general definition of the Laplace transform on an arbitrary time scale, the concepts of the h-Laplace and consequently the discrete Laplace transform were specified in [ 23]. The theory of time scales was initiated by Hilger [ 24]. This theory is a tool that unifies the theories of continuous and discrete time systems. It is a subject of recent studies in many different fields in which dynamic process can be described with discrete or continuous models.

In this paper, starting from the definition of the Sumudu transform on a general time scale, we define the discrete Sumudu transform and present some of its basic properties.

The paper is organized as follows: in Sections 2and 3, we introduce some basic concepts concerning the calculus of time scales and discrete fractional calculus, respectively. In Section 4, we define the discrete Sumudu transform and present some of its basic properties. Section 5is devoted to an application.

2. Preliminaries on Time Scales

A time scale ... is an arbitrary nonempty closed subset of the real numbers ... . The most well-known examples are ... = ... , ... = ... , and ... = ^{q ...} ¯ : = { ^{q n} :n ∈ ... } _... ... {0 } , where q >1 . The forward and backward jump operators are defined by [figure omitted; refer to PDF] respectively, where inf ∅ : =sup ... and sup ∅ : =inf ... . A point t ∈ ... is said to be left-dense if t >inf ... and ρ (t ) =t , right-dense if t <sup ... and σ (t ) =t , left-scattered if ρ (t ) <t , and right-scattered if σ (t ) >t . The graininess function μ : ... [arrow right] [0 , ∞ ) is defined by μ (t ) : = σ (t ) -t . For details, see the monographs [ 25, 26].

The following two concepts are introduced in order to describe classes of functions that are integrable.

Definition 2.1 (see [ 25]).

A function f : ... [arrow right] ... is called regulated if its right-sided limits exist at all right-dense points in ... and its left-sided limits exist at all left-dense points in ... .

Definition 2.2 (see [ 25]).

A function f : ... [arrow right] ... is called rd-continuous if it is continuous at right-dense points in ... and its left-sided limits exist at left-dense points in ... .

The set ^{... κ} is derived from the time scale ... as follows: if ... has a left-scattered maximum m , then ^{... κ} : = ... - {m } . Otherwise, ^{... κ} : = ... .

Definition 2.3 (see [ 25]).

A function f : ... [arrow right] ... is said to be delta differentiable at a point t ∈ ^{... κ} if there exists a number ^{f Δ} (t ) with the property that given any [straight epsilon] >0 , there exists a neighborhood U of t such that [figure omitted; refer to PDF]

We will also need the following definition in order to define the exponential function on an arbitrary time scale.

Definition 2.4 (see [ 25]).

A function p : ... [arrow right] ... is called regressive provided 1 + μ (t )p (t ) ...0;0 for all t ∈ ^{... κ} .

The set ... of all regressive and rd-continuous functions forms an Abelian group under the "circle plus" addition [ecedil]5; defined by [figure omitted; refer to PDF]

The additive inverse [ecedil]6;p of p ∈ ... is defined by [figure omitted; refer to PDF]

Theorem 2.5 (see [ 25]).

Let p ∈ ... and _{t 0} ∈ ... be a fixed point. Then the exponential function _{e p} ( · , _{t 0} ) is the unique solution of the initial value problem [figure omitted; refer to PDF]

3. An Introduction to Discrete Fractional Calculus

In this section, we introduce some basic definitions and a theorem concerning the discrete fractional calculus.

Throughout, we consider the discrete set [figure omitted; refer to PDF]

Definition 3.1 (see [ 27]).

Let f : _{... a} [arrow right] ... and ν >0 be given. Then the νth -order fractional sum of f is given by [figure omitted; refer to PDF] Also, we define the trivial sum by [figure omitted; refer to PDF] Note that the fractional sum operator ^{Δ a - ν} maps functions defined on _{... a} to functions defined on _{... a + ν} .

In the above equation the term (t - σ (s ) ^{) ν -1 _} is the generalized falling function defined by [figure omitted; refer to PDF] for any t , ν ∈ ... for which the right-hand side is well defined. As usual, we use the convention that division by a pole yields zero.

Definition 3.2 (see [ 27]).

Let f : _{... a} [arrow right] ... and ν ...5;0 be given, and let N ∈ ... be chosen such that N -1 < ν ...4;N . Then the νth -order Riemann-Liouville fractional difference of f is given by [figure omitted; refer to PDF]

It is clear that, the fractional difference operator ^{Δ a ν} maps functions defined on _{... a} to functions defined on _{... a +N - ν} .

As stated in the following theorem, the composition of fractional operators behaves well if the inner operator is a fractional difference.

Theorem 3.3 (see [ 27]).

Let f : _{... a} [arrow right] ... be given and suppose ν , μ >0 with N -1 < ν ...4;N . Then [figure omitted; refer to PDF]

A disadvantage of the Riemann-Liouville fractional difference operator is that when applied to a constant c , it does not yield 0. For example, for 0 <v <1 , we have [figure omitted; refer to PDF]

In order to overcome this and to make the fractional difference behave like the usual difference, the Caputo fractional difference was introduced in [ 12].

Definition 3.4 (see [ 12]).

Let f : _{... a} [arrow right] ... and ν ...5;0 be given, and let N ∈ ... be chosen such that N -1 < ν ...4;N . Then the νth -order Caputo fractional difference of f is given by [figure omitted; refer to PDF]

It is clear that the Caputo fractional difference operator ^{C Δ a ν} maps functions defined on _{... a} to functions defined on _{... a +N - ν} as well. And it follows from the definition of the Caputo fractional difference operator that [figure omitted; refer to PDF]

4. The Discrete Sumudu Transform

The following definition is a slight generalization of the one introduced by Jarad et al. [ 28].

Definition 4.1.

The Sumudu transform of a regulated function f : _{... a} [arrow right] ... is given by [figure omitted; refer to PDF] where a ∈ ... is fixed, _{... a} is an unbounded time scale with infimum a and ...9F; {f } is the set of all nonzero complex constants u for which 1 / u is regressive and the integral converges.

In the special case, when _{... a} = _{... a} , every function f : _{... a} [arrow right] ... is regulated and its discrete Sumudu transform can be written as [figure omitted; refer to PDF] for each u ∈ ... \ { -1,0 } for which the series converges. For the convergence of the Sumudu transform, we need the following definition.

Definition 4.2 (see [ 27]).

A function f : _{... a} [arrow right] ... is of exponential order r ( r >0 ) if there exists a constant A >0 such that [figure omitted; refer to PDF]

The following lemma can be proved similarly as in Lemma 12 in [ 27].

Lemma 4.3.

Suppose f : _{... a} [arrow right] ... is of exponential order r >0 . Then [figure omitted; refer to PDF]

The following lemma relates the shifted Sumudu transform to the original.

Lemma 4.4.

Let m ∈ _{... 0} and f : _{... a -m} [arrow right] ... and g : _{... a} [arrow right] ... are of exponential order r >0 . Then for all u ∈ ... \ { -1,0 } such that | ( u +1 ) / u | >r , [figure omitted; refer to PDF]

Proof.

For all u ∈ ... \ { -1,0 } such that | ( u +1 ) / u | >r , we have [figure omitted; refer to PDF]

Taylor monomials are very useful for applying the Sumudu transform in discrete fractional calculus.

Definition 4.5 (see [ 27]).

For each μ ∈ ... \ ( - ... ) , define the μth -Taylor monomial to be [figure omitted; refer to PDF]

Lemma 4.6.

Let μ ∈ ... \ ( - ... ) and a ,b ∈ ... such that b -a = μ . Then for all u ∈ ... \ { -1,0 } such that | (u +1 ) / u | >1 , one has [figure omitted; refer to PDF]

Proof.

By the general binomial formula [figure omitted; refer to PDF] for ν ,x ,y ∈ ... such that |x | < |y | , where [figure omitted; refer to PDF] as in [ 27], it follows from ( 4.10) and [figure omitted; refer to PDF] where k ∈ _{... 0} that [figure omitted; refer to PDF] for ν ∈ ... and |y | <1 .

And since b -a = μ , we have for all u ∈ ... \ { -1,0 } such that | ( u +1 ) / u | >1 , [figure omitted; refer to PDF]

Definition 4.7 (see [ 27]).

Define the convolution of two functions f ,g : _{... a} [arrow right] ... by [figure omitted; refer to PDF]

Lemma 4.8.

Let f ,g : _{... a} [arrow right] ... be of exponential order r >0 . Then for all u ∈ ... \ { -1,0 } such that | ( u +1 ) / u | >r , [figure omitted; refer to PDF]

Proof.

Since [figure omitted; refer to PDF] the substitution τ =k -r yields [figure omitted; refer to PDF] for all u ∈ ... \ { -1,0 } such that | (u +1 ) / u | >r .

Theorem 4.9.

Suppose f : _{... a} [arrow right] ... is of exponential order r ...5;1 and let ν >0 with N -1 < ν ...4;N . Then for all u ∈ ... \ { -1,0 } such that | (u +1 ) / u | >r , [figure omitted; refer to PDF]

Proof.

First note that the shift formula ( 4.5) implies that for all u ∈ ... \ { -1,0 } such that | (u +1 ) / u | >r , [figure omitted; refer to PDF] taking N zeros of ^{Δ a - ν} f into account. Furthermore, by ( 4.9), ( 4.15), and ( 4.16), [figure omitted; refer to PDF] Then we obtain [figure omitted; refer to PDF]

Theorem 4.10.

Suppose f : _{... a} [arrow right] ... is of exponential order r ...5;1 and let ν >0 with N -1 < ν ...4;N . Then for all u ∈ ... \ { -1,0 } such that | (u +1 ) / u | >r , [figure omitted; refer to PDF]

Proof.

Let f ,r , ν , and N be as in the statement of the theorem. We already know from Theorem 3.8 in [ 28] that ( 4.24) holds when ν =N , that is, [figure omitted; refer to PDF] If N -1 < ν <N , then 0 <N - ν <1 and hence it follows from ( 3.6), ( 4.19), and ( 4.25) that [figure omitted; refer to PDF]

In the following theorem the Sumudu transform of the Caputo fractional difference operator is presented.

Theorem 4.11.

Suppose f : _{... a} [arrow right] ... is of exponential order r ...5;1 and let ν >0 with N -1 < ν ...4;N . Then for all u ∈ ... \ { -1,0 } such that | (u +1 ) / u | >r , [figure omitted; refer to PDF]

Proof.

Let f ,r , ν , and N be as in the statement of the theorem. We already know from ( 4.25) that v =N , ( 4.27) holds. If N -1 < ν <N , then 0 <N - ν <1 and hence it follows from ( 4.19) and ( 4.25) that [figure omitted; refer to PDF]

Lemma 4.12.

Let f : _{... a} [arrow right] ... be given. For any p ∈ _{... 0} and ν >0 with N -1 < ν ...4;N , one has [figure omitted; refer to PDF]

Proof.

Let f , v , N , and p be given as in the statement of the lemma. Then [figure omitted; refer to PDF]

Corollary 4.13.

Suppose f : _{... a} [arrow right] ... is of exponential order r ...5;1 , ν >0 with N -1 < ν ...4;N and p ∈ _{... 0} . Then for all u ∈ ... \ { -1,0 } such that | ( u +1 ) / u | >r , [figure omitted; refer to PDF]

Proof.

The proof follows from ( 4.25), ( 4.27), and ( 4.29).

5. Applications

In this section, we will illustrate the possible use of the discrete Sumudu transform by applying it to solve some initial value problems. The following initial value problem was solved in Theorem 23 in [ 27] by using the Laplace transforms.

Example 5.1.

Suppose f : _{... a} [arrow right] ... is of exponential order r ...5;1 and let ν >0 with N -1 < ν ...4;N . The unique solution to the fractional initial value problem [figure omitted; refer to PDF] is given by [figure omitted; refer to PDF] where [figure omitted; refer to PDF] for k ∈ {0,1 , ... ,N -1 } .

Proof.

Since f is of exponential order r , then _{... a} {f } (u ) exists for all u ∈ ... \ { -1,0 } such that | (u +1 ) / u | >r . So, applying the Sumudu transform to both sides of the fractional difference equation in ( 5.1), we have for all u ∈ ... \ { -1,0 } such that | (u +1 ) / u | >r , [figure omitted; refer to PDF] Then from ( 4.24), it follows [figure omitted; refer to PDF] and hence [figure omitted; refer to PDF] By ( 4.20), we have [figure omitted; refer to PDF] Considering the terms in the summation, by using the shifting formula ( 4.5), we see that for each k ∈ {0,1 , ... ,N -1 } , [figure omitted; refer to PDF] since [figure omitted; refer to PDF] for i ∈ {0 , ...k -1 } .

Consequently, we have [figure omitted; refer to PDF] Since Sumudu transform is a one-to-one operator (see [ 28, Theorem 3.6]), we conclude that for t ∈ _{... a + ν -N} , [figure omitted; refer to PDF] where [figure omitted; refer to PDF] (see [ 27, Theorem 11]).

Example 5.2.

Consider the initial value problem ( 5.1) with the Riemann-Liouville fractional difference replaced by the Caputo fractional difference. [figure omitted; refer to PDF]

Applying the Sumudu transform to both sides of the difference equation, we get for all u ∈ ... \ { -1,0 } such that | (u +1 ) / u | >r , [figure omitted; refer to PDF]

Then from ( 4.27), it follows [figure omitted; refer to PDF] By ( 4.20), we have [figure omitted; refer to PDF] Since from [ 28], we have [figure omitted; refer to PDF] hence [figure omitted; refer to PDF]

Remark 5.3.

The initial value problem ( 5.1) can also be solved by using Proposition 15 in [ 12].

Example 5.4.

Consider the initial value problem [figure omitted; refer to PDF] where 0 < ν ...4;1 . Applying the Sumudu transform to both sides of the equation and using ( 4.31) and ( 4.27), respectively, we get [figure omitted; refer to PDF] Hence we get [figure omitted; refer to PDF] Since from [ 28], we have [figure omitted; refer to PDF] then [figure omitted; refer to PDF]