Solving Generalized Wave and Heat Equations Using Linear Canonical Transform and Sampling Formulae

Several essential properties of the linear canonical transform (LCT) are provided. Some results related to the sampling theorem in the LCT domain are investigated. Generalized wave and heat equations on the real line are introduced, and their solutions are constructed using the sampling formulae. Some examples are presented to illustrate our results.


Introduction
The linear canonical transform (LCT) is one of nontrivial generalizations of the Fourier transform (FT). Recently, the LCT has been investigated extensively both in theory and applications. In the connection with the LCT theory, many interesting papers on this topic have been already available in the literature (see [1][2][3][4][5]). From the applied point of view, the LCT also has been widely used in various areas such as optics, radar system analysis, phase retrieval, pattern recognition, and many other applications (see [6][7][8]).
It is known that the wave and heat equations are important in mathematical physics, applied mathematics, and engineering. Common methods to solve these equations are the Fourier and Laplace transforms, which give their exact solutions. The other techniques to have the solutions of these equations are the variation iteration method and the domain decomposition method, which coresponds to the adomian decomposition method [9]. Recently, the fundamental solution of the generalized wave equation was obtained using the fractional Fourier transform (FrFT) by [10]. Since the LCT is a general form of the FrFT and also it is closely related to the FT, it is possible to extend wave and heat equations into the LCT domain. However, as far as we observe, up to now, the solution of generalized heat equation using the sampling formulae and the LCT has not yet been published in the literature. Therefore, in the present article, we provide useful properties and examples of the LCT. We will consider the wave equation in the LCT domain, and we will explore the solution of this equation using the LCT as exact analytic tool for solutions. We find a relation that the solution of the wave equation using the FT and the FrFT is a special case of the solution of these generalized wave equation. We explicitly discuss a generalized version of the heat equation in the LCT domains. Based on the sampling formulae related to the LCT, we further derive its solution followed by using the LCT. We emphasize that our solutions are nontrivial generalizations of the solutions of the heat equation using the sampling formulae and FT methods. For implementations, we finally provide a few examples to illustrate our results.
The remnants of the article are organized as follows: Section 2 introduces definitions and examples of the LCT, which will be needed in the sequel. The useful properties of the LCT are presented in Section 3. Some results related to the sampling theorems are demonstrated in Section 4. A general form of wave equation in the LCT domain is provided in Section 5. A general form of heat equation in the LCT domain and its solution using the sampling formulae are presented in Section 6. Its solution using LCT is discussed in detail in Section 7. Finally, Section 8 concludes our article.

Linear Canonical Transform
Stuart A. Collin [11] introduced the linear canonical transforms (LCTs) during the early 1970s in paraxial optics. Independently, Moshinsky and Quesne [12] studied LCTs in quantum mechanics. Recently, Wolf [13] discussed in detail the development of LCTs including several complex extensions of the LCTs.
Let us start with the definition of the several dimensional linear canonical transform: [12,13]). For an arbitrary 2N × 2N symplectic matrix the N-dimensional of the linear canonical transform (LCT) is then defined as where where i 2 = −1.
Here, E is invertible and its inverse is given by Secondly, let us introduce the inversion formula. Because of then, inversion formula of (2) has the following form: To solve the generalized wave and heat equations, we will only deal with the case that N = 1. When N = 1, Definition 1 mentioned above becomes where K E ðξ, tÞ is so-called kernel of the LCT given by and the matrix parameter E = a b c d " # satisfies det ðEÞ = ad − bc = 1, that is, E ∈ Slð2, ℝÞ, which denotes the special linear group over ℝ.
Based on (5), the LCT kernel (8) satisfies where f ★ stands for the complex conjugation of f . Equation (7) implies that for b = 0, the LCT of a signal is essentially a chirp multiplication. Therefore, we only consider the case of b ≠ 0 in this work. In the special case where E = 0 1 , the LCT mentioned above reduces to the Fourier transform (FT), that is, Here, the FT and its inverse are defined by (see [14][15][16]) provided that the integral exists. The connection between the FT and LCT is given by An application of (9), we get the inverse transform of the LCT, that is, Or, equivalently, Abstract and Applied Analysis where provided Reðia/bÞ < 0. For a is a real number, b must satisfy −π < arg b < 0. For an example, taking a = 2 −1/2 = d, b = i 2 −1/2 = c, we obtain (compare to [17]) The next, following [13], we have.
This form is often so-called heat kernel or Gauss's kernel.
Definition 4. The inversion formula of the complex LCT is defined as in [13,17]. where Example 5. (Dirac delta function). The Dirac delta function δðtÞ is a generalized function satisfying the following: By applying (7) to δðtÞ, we obtain Example 6. (Gaussian function). The Gaussian function is defined by The LCT of the Gaussian function gðtÞ is given by (see [1]) Let us introduce the convolution of two complex functions in the LCT domain and the relationship between the convolution and its LCT (see [5,[18][19][20]).
Definition 7. Let f , g ∈ L 1 ðℝÞ. Then, the convolution operator associated with the LCT is given by The LCT of the convolution of f and g is given by

Useful Properties of LCT
The following Theorem 8 describes the LCT of the derivative of a function (see [21]). It is very useful to solve partial differential equations related to the LCT.
Theorem 8. Let f ðtÞ ∈ L 1 ðℝÞ. Assume that L E fðd n /dt n Þf ðtÞ gðξÞ exist. Then, we have Let us give a simple application of Theorem 8.
Example 9. (Mexican hat wavelet). The Mexican hat wavelet is defined by (see [22]) The alternative form of (28) is The LCT of (28) is given by Let us give a sketch of the proof of (30) below. By applying Theorem 8 with n = 2 and Example 6, we get Abstract and Applied Analysis By algebraic simplifications, we obtain Now, setting h = 1/2ðððac + bdÞi − 1/a 2 + b 2 ÞÞ, we get Definition 10. The Schwartz space SðℝÞ of rapidly decaying functions is defined by a collection of complex valued functions such that where D = d/dt.
The generalization of the Schwartz space in the LCT domain is described in the following.
Definition 11. ( [21]). The Schwartz space S E ðℝÞ of rapidly decaying functions associated with the LCT is defined by a collection of complex valued functions such that where From the above definition, we obtain the following important result (see [21]).

Theorem 12.
Let K E ðξ, tÞ be the LCT kernel and

Sampling Theorem in LCT Domain
The sampling theorem [23] states that a class of functions can be determined perfectly from samples taken at equal interval. In this part, we investigate some results of sampling theorem associated with the LCT. We first introduce the following result, which was investigated in [24,25].
Theorem 13. Suppose that f is band limited to Ω E in the LCT domain. Then, for every x and b > 0, one has Here, T = πb/Ω E , and it is the sampling period. This gives the following theorem which is very useful to obtain the solution of heat equation in the LCT domain.

Theorem 14.
Under assumptions as in Theorem 13, we have where the step function is defined by Proof. Substituting (37) into the LCT definition, it is not difficult to arrive at 4 Abstract and Applied Analysis This is the desired result.

Generalized Wave Equations in Linear Canonical Transform Domain
In the present section, we study how the LCT can be applied to solve partial differential equations. In particular, we are going to obtain the solution of generalized wave equation. In [26], the author have obtained the solution of wave equation using the LCT. Therefore, in this part, we propose a different way to obtain the solution of wave equations related to the LCT. We also provide a simple example to illustrate the result. Let us therefore introduce the generalized wave equation in the LCT domain. Consider the following generalized one-dimensional wave equation associated with the LCT: with the initial condition: where k is a positive constant and f ðxÞ, gðxÞ ∈ L 1 ðℝÞ. Note that D E = −d/dx − iða/bÞx. The solution of the generalized one-dimensional wave equation mentioned above is given by which is the solution of the generalized wave equation using the FrFT (compare to [10]). Therefore, (43) can be seen as follows: For fixed t, applying the LCT on both sides of (41) and using Theorem 12, we obtain where ϕ E ðξ, tÞ = L E fϕðx, tÞg is the LCT of ϕðx, tÞ with respect to x only. The solution of equation (46) takes the form: Differentiating (47) with respect to t, we have Now, we use the notation Consequently, we obtain From equations (51) and (52), we get Now, applying inverse transform of the LCT defined by (14) into both sides of (55), we immediately get Set f ðεÞ = f ðεÞe iða/2bÞε 2 , gðεÞ = gðεÞe iða/2bÞε 2 , and v = ξ/b, then we have By using the FT definition (11), we immediately obtain as claimed in (43). For different values of (43) is shown in Figures 1 and 2.
For an illustration, we provide the following simple example. 6 Abstract and Applied Analysis Example 5.1 Let us consider the following initial wave equation: According to (43), we get the solution in the form: Abstract and Applied Analysis Based on Gaussian integral and basic property of matrix parameter of the LCT, we obtain Put hðx, tÞ = e 1/2ð−b 2 c−2ak 2 it/2k 2 bt−ib 2 dÞx 2 . Then, we get From (70), we obtain

Conclusion
We have established the solution of generalized wave equation using the lCT and obtained the solution of heat equation using the sampling formulae of band limited function related to the LCT. The solutions have been obtained by applying the properties of the LCT and the relationship between the FT and the LCT. It is found that the solutions are general form of the solutions of the classical wave and heat equations.

Data Availability
All data generated or analyzed during this study are included in this published paper.

Conflicts of Interest
The authors declare that they have no conflicts of interest.