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1. Introduction

Wavelets were first developed by Haar, a Hungarian mathematician, in his Ph.D. thesis in 1909 [1]. Wavelets are a group of self-similar mathematical functions used to solve various kinds of complex functions in a simple way. Wavelet analysis is related to Fourier analysis because both allow a function to be written in the form of basis functions [2]. These sine trigonometric functions are the foundation functions of Fourier analysis. Wavelet analysis, on the other hand, uses a specifically constructed collection of self-similar, orthonormal basis functions that are spatially and temporally connected. Wavelets have been widely used in biology [3], chemistry [4], physics [5], engineering [6], and mathematics [7], and they have remained a popular choice in numerical analysis [8] because they often outperform traditional approaches. Discrete wavelets [9] and continuous wavelets [10] constitute the wavelet class. A finite energy signal is projected onto a family of bands of frequencies or similar subdomains of the Lp function space $L^2\left(R\right)$ using continuous wavelet transforms. The signal could be represented on any frequency band of the form [f, 2f] for any positive frequency. After that, a sufficient integration over all of the created frequency components can be used to recover the original signal. One may wonder if choosing a discrete subset of the upper half-plane is sufficient to reconstruct a signal using the right wavelet coefficients, even when it is computationally impractical to analyze a signal using all of the wavelet coefficients. The affine system for some real parameters is one example of such a system. $b>0$, $a>1$. The Hermite wavelet, introduced by a French mathematician, is one of the continuous wavelets [8]. They are created by the dilation and translation of a single function, known as the mother wavelet or analyzing wavelet. We can easily and simply solve a variety of IEs [11], ODEs [8], PDEs [12], and fractional-order DEs. The BTE is a well-known equation of the fractional-order differential equation [13]. BTE is a type of fractional DE that is found in many mathematical fields. Fractional-differential equations arise in a wide range of applications across various scientific fields. They are used in rheology to study polymers [14] and thermodynamical changes [15], in hemodynamics to analyze blood flow [16], and in electrodynamics to model complex and congested media [17]. These equations also play a crucial role in understanding viscoelasticity [18], biological phenomena in physics [19], and electrical signal behavior in various contexts [20]. Additionally, they find applications in chemistry [21], biological systems [22], experimental data analysis [23], and physical phenomena [24]. Their relevance extends further to aerodynamics [25], modeling earthquake vibrations [26], and many other scientific and engineering domains. The aforementioned equation is a concept FDE that was initially studied by two scientists, Bagley and Torvik, as a way to apply fractional mathematics to the the viscoelasticity phenomenon [27]. For approximate solutions of these kinds of equations, a number of numerical techniques have been contributed. These include the approximation process [28], the Adams predictor and corrector method [28], the Taylor collocation method [29], the spline method [30], and many others. Furthermore, Svatoslav Staněk examined whether there are any solutions to the generalized BTE that are unique and subject to boundary conditions [31]. Among them, wavelet-based approaches have gained popularity because to their ability to efficiently handle highly oscillatory and non-smooth solutions, as well as their computing efficiency in decreasing issue complexity. Similarly, approaches based on collocation, orthogonal polynomials, and matrix representations of fractional derivatives have shown promise for improving accuracy and efficiency. By Comparing this method performance to older procedures, assessing their convergence, and applicability to real-world issues. By addressing these objectives, the study hopes to add to the expanding body of knowledge on numerical methods for FDEs while also providing insights into the actual application of fractional-order differential equation in engineering and science. This study focusses on creating and analyzing numerical methods for solving the fractional-order Bagley-Torvik equation, with an emphasis on accuracy and computation. Specifically, this research attempts to examine the numerical hurdles presented by the fractional derivative term, notably its memory-intensive computations.

In this study, the HWM technique [8], which is based on the Hermite polynomial $N_j\left(y\right)$, is used. In this terminology, we investigate the approximate solution of an unknown function using the Hermite wavelet in which the collocation points are taken. By the utilizing collocation points, a system of algebraic equations is obtained for the given differential equation, which needs to be approximated. Then, we solve the system of equations simultaneously and obtain the series solution to the given differential equation. Through this method, many differential equations have been solved, but it has not been extended to the fractional order nor applied to the fractional-order Bagley–Torvik equation. Therefore, in this study, the Hermite wavelet is used to apply it to fractional-order DE problems. The objectives of this study is to understand the HWM wavelet method to investigate fractional-order BTE. For checking the validity, we apply the given procedure to some test experiments. The study makes significant contributions to the subject of fractional-differential equations, particularly for the solution of the fractional-order Bagley–Torvik equation using the Hermite Wavelet method. This is the first time Hermite wavelets have been applied to such equations, proving their capacity to deal with fractional derivatives and high oscillatory behavior effectively. The method improves the computational efficiency by lowering the issue dimensionality and obtaining fast convergence, exceeding several existing numerical techniques. Furthermore, it improves accuracy when approximating fractional derivatives, particularly in circumstances when traditional approaches fail due to the fractional character of the operators. The major contributions to this study of solving the fractional-order Bagley–Torvik equation by applying the Hermite wavelet method are as follows,

• Introducing an efficient computational algorithm utilizing Hermite wavelets to approximate the solution of the fractional-order Bagley–Torvik equation.

• Demonstrating the superiority of the Hermite wavelet method in terms of accuracy and computational efficiency when compared with other numerical methods for fractional-order differential equations.

• Addressing challenges such as singularities and highly oscillatory behavior inherent in fractional-order equations using Hermite wavelets, offering improved numerical stability and convergence.

• It opens avenues for further research by demonstrating the feasibility of Hermite wavelets for other types of fractional-partial-differential equations and their applications in fields such as bioengineering, finance, and materials science, and many more.

The organization of this article is as, in Section 1, the “Introduction” is given; in Section 2, “Basic Concepts” are included; Section 3 contains the “Hermit wavelet method”; Section 4 contains the “Error analysis of the HWM method”; in Section 5, “Test Experiments” is given; and the last Section 6 contains the “Conclusions”.

2. Basic Concepts

In this portion, we provide some basic concepts about the present study that help us in our discussion.

(1) ${\displaystyle \frac{dy}{dz}}=3y,wherez\left(0\right)=1.$

(2) ${\displaystyle \frac{d^{3}y}{d{z}^3}}=3y^3+2y,wherez\left(0\right)=1,z^{\prime }\left(0\right)=1,z^{″}\left(1\right)=2.$

3. Hermite Wavelet Method

Algorithm for Function Approximation to Obtain the Solution

Consider a Bagley–Torvik equation of a fractional order.

(8)$z^{\left(s\right)}\left(y\right)+\epsilon T^{\left(k\right)}\left(y\right)+\delta z\left(y\right)=g\left(y\right),kisfraction,s\in {\mathbb{Z}}^{+},$

$z\left(0\right)=c_0,z\left(r\right)=c_r,$

(9)$z^{\left(s\right)}\left(0\right)=d_0,z^{\left(s\right)}\left(r\right)=d_r.$

(10)$T^{\alpha }g\left(t\right)={\displaystyle \frac{1}{\Gamma (l-\alpha )}}{\displaystyle \frac{d^l}{d{t}^l}}{\int }_0^t{\displaystyle \frac{g\left(s\right)}{{(t-s)}^{\alpha -l+1}}}ds,\alpha >0.$

(11)$z\left(y\right)=\sum _{s=1}^{\infty }\sum _{j=0}^{\infty }{\mathsf{\Omega }}_{s,j}\phi \left(y\right),$

(12)${\phi }_{s,j}\left(y\right)=\left\{\begin{array}{cc}\frac{2^{\frac{r+1}{2}}}{\surd \pi }{\aleph }_j(2^{r}y-2s+1),\hfill & \frac{s-1}{2^{r-1}}\le y<{\displaystyle \frac{s}{2^{r-1}}},\hfill \\ 0,\hfill & otherwise,\hfill \end{array}\right.$

Also, ${\aleph }_j\left(y\right)$ is as follows

(13)$\begin{array}{cc}\hfill {\aleph }_0& =1,\hfill \\ \hfill {\aleph }_1& =2y,\hfill \\ \hfill ⋮\\ \hfill {\aleph }_{j+2}& =2y{\aleph }_{j+1}\left(y\right)-2(j+1){\aleph }_j\left(y\right),\hfill \end{array}$

To find $z\left(y\right)$ numerically, we truncate the series represented in Equation (11)

(14)$z\left(y\right)\approx \sum _{s=1}^{2^{r-1}}\sum _{j=0}^{J-1}{\mathsf{\Omega }}_{s,j}\phi \left(y\right)={\mathsf{\Omega }}^T\phi \left(y\right),$

(15)${\mathsf{\Omega }}^T=[{\mathsf{\Omega }}_{1,0},...,{\mathsf{\Omega }}_{1,J-1},{\mathsf{\Omega }}_{2,0},...,{\mathsf{\Omega }}_{2,J-1},...,{\mathsf{\Omega }}_{2^{r-1},0},...,{\mathsf{\Omega }}_{2^{r-1},J-1}],$

(16)$\phi \left(y\right)={[{\phi }_{1,0},...,{\phi }_{1,J-1},{\phi }_{2,0},...,{\phi }_{2,J-1},...,{\phi }_{2^{r-1},0},...,{\phi }_{2^{r-1},J-1}]}^T,$

Using Equations (8)–(16), we obtain the numerical procedure for Equations (8) and (9).

4. Error Analysis of HWM Method

Assume that there exists a function $u\left(x\right)$, such that $u^{\prime }\left(x\right)$

$u\left(x\right)\le L,\mathrm{for}\mathrm{all}x\in (a,b),$

$u\left(x\right)\le M,\mathrm{where}M\in {\mathbb{R}}^{+}.$

The function $u\left(x\right)$ approximation by HWM is provided by

$u_j\left(x\right)={\mathsf{\Sigma }}_{i=1}^{2j}{\alpha }_i\chi \left(x\right).$

It has already been demonstrated by Babolian and Shahsavaran [33] that the wavelet error approximation

$\parallel u\left(x\right)-u_j\left(x\right)\parallel ={\displaystyle \frac{M^3}{3{\left(2J\right)}^2}}.$

Therefore,

(17)$\parallel u\left(x\right)-u_j\left(x\right)\parallel =O\left({\displaystyle \frac{1}{J}}\right).$

It is evident from Equation (17) that the inaccuracy is inversely proportional to the Hermite wavelet’s resolution level. This indicates that as J increases, so does the rate of convergence of the Hermite wavelet approximation.

5. Test Experiments

This section contains various test problems to assess the validity of the proposed method in this study. The results that were obtained using the proposed method demonstrate that the current method is more effective and simpler for FDEs. We use the developed approach to provide numerical solutions to the following problems with boundary values of fractional-order DEs using HWM.

(18)$\begin{array}{ccc}\hfill z^{\left(2\right)}\left(y\right)+{\displaystyle \frac{1}{2}}T+{\displaystyle \frac{1}{2}}z\left(y\right)-8& =& 0,0<y<1,whereT=D^{{\displaystyle \frac{2}{3}}}\left(y\right),\hfill \end{array}$

(19)$\begin{array}{c}\hfill z\left(0\right)=1,z^{\prime }\left(0\right)=0,\end{array}$

The exact solution is

(20)$z=1+3.714y^2.$

By using the above proposed method (HWM), solving this problem for r = 1 and J = 10. To approximate $z\left(y\right)$, truncating the series using Equation (7) as

(21)$z\left(y\right)\approx \sum _{j=0}^{10-1}{\mathsf{\Omega }}_{1,j}\phi \left(y\right)={\mathsf{\Omega }}^T\phi \left(y\right),$

(22)${\phi }_{s,j}\left(y\right)=\left\{\begin{array}{cc}\frac{2^{\frac{r+1}{2}}}{\surd \pi }{\aleph }_j(2^{r}y-2s+1),\hfill & \frac{s-1}{2^{r-1}}\le y<{\displaystyle \frac{s}{2^{r-1}}},\hfill \\ 0,\hfill & otherwise,\hfill \end{array}\right.$

The Hermite polynomial becomes the following

${\aleph }_0=1,$

${\aleph }_1=2y$

${\aleph }_2=4y^2$

${\aleph }_3=8y^3-4y$

${\aleph }_4=16x^4-24x^2$

${\aleph }_5=32x^5-96x^3+24x$

$\begin{array}{cc}\hfill {\aleph }_6& =64x^6-320x^4+240x^2\hfill \\ \hfill ⋮\end{array}$

$\begin{array}{cc}\hfill {\aleph }_{11}& =2048x^{11}-46080x^9+322560x^7-806400x^5+604800x^3-60480x.\hfill \end{array}$

Similarly

${\mathsf{\Omega }}_{1,0}=0.7511255444,$

${\mathsf{\Omega }}_{1,1}=3.004502178x-1.502251089,$

${\mathsf{\Omega }}_{1,2}=3.004502178{(2x-1)}^2,$

${\mathsf{\Omega }}_{1,3}=48.07203484x^3-72.10805226x^2+30.04502178x-3.004502177,$

${\mathsf{\Omega }}_{1,4}=192.2881394x^4-384.5762787x^3+216.3241567x^2-24.03601740x-6.00900436,$

$\begin{array}{cc}\hfill {\mathsf{\Omega }}_{1,5}=& 769.1525574x^5-1922.881394x^4+1346.016976x^3-96.1440697x^2-156.2341133x\hfill \\ \hfill & +30.04502177,\hfill \end{array}$

$\begin{array}{cc}\hfill {\mathsf{\Omega }}_{1,6}=& 3076.610230x^6-9229.830689x^5+7691.525573x^4-12.0180087-2163.241568x^2\hfill \\ \hfill & +624.936453x,\hfill \end{array}$

$\begin{array}{c}\hfill ⋮\\ \hfill {\mathsf{\Omega }}_{1,9}=& -8.860637461\times {10}^5{x}^8+1.082966800\times {10}^6{x}^7+3.44580346\times {10}^5{x}^6\hfill \\ \hfill & -1.421393926\times {10}^6{x}^5+6.245518771\times {10}^5{x}^4+2.04594579\times {10}^5{x}^3-1.684444099\hfill \\ \hfill & \times {10}^5{x}^2+17354.00455x+2475.709791+1.969030547\times {10}^5{x}^9\hfill \end{array}$

By putting the values of $\mathsf{\Omega }$s and $\varphi \left(y\right)$ in Equation (21) and then solving with the help of Maple software, we obtain

(23)$\begin{array}{cc}\hfill z\left(y\right)=& 2.04594579\times {10}^5{\mathsf{\Omega }}_{1,9}{x}^3-1.684444099\times {10}^5{\mathsf{\Omega }}_{1,9}{x}^2+6.24551877\times {10}^5{\mathsf{\Omega }}_{1,9}{x}^4+3.44580346\hfill \\ \hfill & \times {10}^5{\mathsf{\Omega }}_{1,9}{x}^6+1.082966800\times {10}^6{\mathsf{\Omega }}_{1,9}\times x^7-8.860637461\times {10}^5\times {\mathsf{\Omega }}_{1,9}{x}^8+1.969030547\hfill \\ \hfill & \times {10}^5{\mathsf{\Omega }}_{1,9}{x}^9-1.421393926\times {10}^6{\mathsf{\Omega }}_{1,9}{x}^5-9133.68661{\mathsf{\Omega }}_{1,8}x+17354.00455{\mathsf{\Omega }}_{1,9}x\hfill \\ \hfill & +11441.1443{\mathsf{\Omega }}_{1,8}{x}^2+75376.9505{\mathsf{\Omega }}_{1,8}{x}^3+43072.5431{\mathsf{\Omega }}_{1,8}{x}^5+49225.76369{\mathsf{\Omega }}_{1,8}{x}^8\hfill \\ \hfill & -1.884423765\times {10}^5{\mathsf{\Omega }}_{1,8}\times x^4+2.153627162\times {10}^5{\mathsf{\Omega }}_{1,8}{x}^6-1.969030547\times {10}^5{\mathsf{\Omega }}_{1,8}\times x^7\hfill \\ \hfill & +264.396193{\mathsf{\Omega }}_{1,7}x-22113.13603{\mathsf{\Omega }}_{1,7}{x}^3+7787.66964{\mathsf{\Omega }}_{1,7}\times x^2+41534.23810{\mathsf{\Omega }}_{1,7}{x}^5\hfill \\ \hfill & +3845.76279{\mathsf{\Omega }}_{1,7}{x}^4-43072.54322{\mathsf{\Omega }}_{1,7}{x}^6+624.936453{\mathsf{\Omega }}_{1,6}x+12306.44092{\mathsf{\Omega }}_{1,7}\times x^7\hfill \\ \hfill & +7691.525573{\mathsf{\Omega }}_{1,6}{x}^4-2163.241568{\mathsf{\Omega }}_{1,6}{x}^2+3076.610230{\mathsf{\Omega }}_{1,6}{x}^6-9229.830689{\mathsf{\Omega }}_{1,6}{x}^5\hfill \\ \hfill & +1346.016976{\mathsf{\Omega }}_{1,5}\times x^3-96.1440697{\mathsf{\Omega }}_{1,5}{x}^2-156.2341133{\mathsf{\Omega }}_{1,5}x-24.03601740{\mathsf{\Omega }}_{1,4}x\hfill \\ \hfill & +769.1525574{\mathsf{\Omega }}_{1,5}{x}^5-1922.881394{\mathsf{\Omega }}_{1,5}{x}^4+192.2881394{\mathsf{\Omega }}_{1,4}\times x^4-384.5762787{\mathsf{\Omega }}_{1,4}{x}^3\hfill \\ \hfill & +216.3241567{\mathsf{\Omega }}_{1,4}{x}^2-12.01800871{\mathsf{\Omega }}_{1,2}x+48.07203484{\mathsf{\Omega }}_{1,3}{x}^3-72.10805226{\mathsf{\Omega }}_{1,3}\times x^2\hfill \\ \hfill & +30.04502178{\mathsf{\Omega }}_{1,3}x+3.004502178{\mathsf{\Omega }}_{1,1}x+12.01800871{\mathsf{\Omega }}_{1,2}{x}^2-1.502251089{\mathsf{\Omega }}_{1,1}\hfill \\ \hfill & +0.7511255444{\mathsf{\Omega }}_{1,0}-3.004502177{\mathsf{\Omega }}_{1,3}+3.004502178{\mathsf{\Omega }}_{1,2}+30.04502177{\mathsf{\Omega }}_{1,5}-6.00900436\hfill \\ \hfill & \times {\mathsf{\Omega }}_{1,4}-276.4142004{\mathsf{\Omega }}_{1,7}-12.0180087{\mathsf{\Omega }}_{1,6}+697.044505{\mathsf{\Omega }}_{1,8}+2475.709791{\mathsf{\Omega }}_{1,9},\hfill \end{array}$

$T={\displaystyle \frac{1}{\Gamma (l-\alpha )}}{\displaystyle \frac{d^l}{d{x}^l}}{\int }_0^x{\displaystyle \frac{1+z}{{(x-z)}^{(\alpha -l+1)}}}dz,$

Also solving the initial conditions (19) using the proposed method and with the help of Maple, we obtain

(24)$\begin{array}{cc}\hfill & 2475.709791{\mathsf{\Omega }}_{1,9}+697.044505{\mathsf{\Omega }}_{1,8}-276.4142004{\mathsf{\Omega }}_{1,7}-12.0180087{\mathsf{\Omega }}_{1,6}+30.04502177{\mathsf{\Omega }}_{1,5}\hfill \\ \hfill & -6.00900436{\mathsf{\Omega }}_{1,4}-3.004502177{\mathsf{\Omega }}_{1,3}+3.004502178{\mathsf{\Omega }}_{1,2}-1.502251089{\mathsf{\Omega }}_{1,1}+0.7511255444\hfill \\ \hfill & {\mathsf{\Omega }}_{1,0}=1,\hfill \end{array}$

(25)$\begin{array}{cc}\hfill & 17354.00455{\mathsf{\Omega }}_{1,9}-9133.68661{\mathsf{\Omega }}_{1,8}+264.396193{\mathsf{\Omega }}_{1,7}+624.936453{\mathsf{\Omega }}_{1,6}-156.2341133{\mathsf{\Omega }}_{1,5}\hfill \\ \hfill & -24.03601740{\mathsf{\Omega }}_{1,4}+30.04502178{\mathsf{\Omega }}_{1,3}-12.01800871{\mathsf{\Omega }}_{1,2}+3.004502178{\mathsf{\Omega }}_{1,1}=0,\hfill \end{array}$

Then, we have to collocate Equation (13) by limiting points of the following sequence, to obtain the remaining three equations,

(26)$\left\{y_i\right\}=\left\{{\displaystyle \frac{1}{2}}(1+cos{\displaystyle \frac{(i-1)\pi }{9}})\right\},$

• we obtain,

  (27)$\begin{array}{cc}\hfill & -7.656858633-41934.90629{\mathsf{\Omega }}_{1,9}+43266.93405{\mathsf{\Omega }}_{1,8}-2396.177737{\mathsf{\Omega }}_{1,7}-2527.606491{\mathsf{\Omega }}_{1,6}\hfill \\ \hfill & +587.0772524{\mathsf{\Omega }}_{1,5}+109.3490420{\mathsf{\Omega }}_{1,4}-96.03279185{\mathsf{\Omega }}_{1,3}+24.70368457{\mathsf{\Omega }}_{1,2}\hfill \\ \hfill & -0.5007503633{\mathsf{\Omega }}_{1,1}+0.3755627722{\mathsf{\Omega }}_{1,0}=0\hfill \end{array}$

(28)$\begin{array}{cc}\hfill & -7.592339865+89025.97558{\mathsf{\Omega }}_{1,9}+18388.17142{\mathsf{\Omega }}_{1,8}-6754.344199{\mathsf{\Omega }}_{1,7}-598.4255156{\mathsf{\Omega }}_{1,6}\hfill \\ \hfill & +599.2907485{\mathsf{\Omega }}_{1,5}-31.81356118{\mathsf{\Omega }}_{1,4}-63.69214905{\mathsf{\Omega }}_{1,3}+24.33275838{\mathsf{\Omega }}_{1,2}\hfill \\ \hfill & -0.3338335752{\mathsf{\Omega }}_{1,1}+0.3755627723{\mathsf{\Omega }}_{1,0}=0\hfill \end{array}$

(29)$\begin{array}{cc}\hfill & -7.569038806+90268.21205{\mathsf{\Omega }}_{1,9}-8867.598683{\mathsf{\Omega }}_{1,8}-5130.060791{\mathsf{\Omega }}_{1,7}+890.6470606{\mathsf{\Omega }}_{1,6}\hfill \\ \hfill & +361.8608406{\mathsf{\Omega }}_{1,5}-116.1594305{\mathsf{\Omega }}_{1,4}-31.74716087{\mathsf{\Omega }}_{1,3}+24.11020266{\mathsf{\Omega }}_{1,2}-0.1669167876\hfill \\ \hfill & \times {\mathsf{\Omega }}_{1,1}+0.3755627721{\mathsf{\Omega }}_{1,0}=0,\hfill \end{array}$

(30)$\begin{array}{cc}\hfill & -7.558278538-0.1250958913e^{-2}{\mathsf{\Omega }}_{1,9}-20190.25446{\mathsf{\Omega }}_{1,8}-0.4003068522e^{-5}{\mathsf{\Omega }}_{1,7}\hfill \\ \hfill & +1442.161028{\mathsf{\Omega }}_{1,6}+0.2481068511e^{-5}{\mathsf{\Omega }}_{1,5}-144.2161044{\mathsf{\Omega }}_{1,4}-2.918904131\times {10}^{-8}{\mathsf{\Omega }}_{1,3}\hfill \\ \hfill & +24.03601744{\mathsf{\Omega }}_{1,2}-2.084931522\times {10}^{-10}{\mathsf{\Omega }}_{1,1}+0.3755627723{\mathsf{\Omega }}_{1,0}=0,\hfill \end{array}$

(31)$\begin{array}{cc}\hfill & -7.552744381-90268.21778{\mathsf{\Omega }}_{1,9}-8867.598598{\mathsf{\Omega }}_{1,8}+5130.060750{\mathsf{\Omega }}_{1,7}+890.6470311{\mathsf{\Omega }}_{1,6}\hfill \\ \hfill & -361.8608365{\mathsf{\Omega }}_{1,5}-116.1594305{\mathsf{\Omega }}_{1,4}+31.74716088{\mathsf{\Omega }}_{1,3}+24.11020268{\mathsf{\Omega }}_{1,2}+0.1669167878\hfill \\ \hfill & \times {\mathsf{\Omega }}_{1,1}+0.3755627722{\mathsf{\Omega }}_{1,0}=0,\hfill \end{array}$

(32)$\begin{array}{cc}\hfill & -7.549788394-89025.98136{\mathsf{\Omega }}_{1,9}+18388.17114{\mathsf{\Omega }}_{1,8}+6754.344218{\mathsf{\Omega }}_{1,7}-598.4255076{\mathsf{\Omega }}_{1,6}\hfill \\ \hfill & -599.2907448{\mathsf{\Omega }}_{1,5}-31.81356155{\mathsf{\Omega }}_{1,4}+63.69214905{\mathsf{\Omega }}_{1,3}+24.33275837{\mathsf{\Omega }}_{1,2}+0.3338335753\hfill \\ \hfill & \times {\mathsf{\Omega }}_{1,1}+0.3755627721{\mathsf{\Omega }}_{1,0}=0,\hfill \end{array}$

(33)$\begin{array}{cc}\hfill & -7.548245092+41934.89622{\mathsf{\Omega }}_{1,9}+43266.93424{\mathsf{\Omega }}_{1,8}+2396.177687{\mathsf{\Omega }}_{1,7}-2527.606519{\mathsf{\Omega }}_{1,6}\hfill \\ \hfill & -587.0772495{\mathsf{\Omega }}_{1,5}+109.3490413{\mathsf{\Omega }}_{1,4}+96.03279174{\mathsf{\Omega }}_{1,3}+24.70368457{\mathsf{\Omega }}_{1,2}\hfill \\ \hfill & +0.5007503628{\mathsf{\Omega }}_{1,1}+0.3755627724{\mathsf{\Omega }}_{1,0}=0,\hfill \end{array}$

(34)$\begin{array}{cc}\hfill & -7.547532296+2.488323020\times {10}^5{\mathsf{\Omega }}_{1,9}+41351.59957{\mathsf{\Omega }}_{1,8}-8356.417689{\mathsf{\Omega }}_{1,7}-4064.338846\hfill \\ \hfill & \times {\mathsf{\Omega }}_{1,6}-198.4447900{\mathsf{\Omega }}_{1,5}+308.2076130{\mathsf{\Omega }}_{1,4}+128.9669166{\mathsf{\Omega }}_{1,3}+25.22298125\times {\mathsf{\Omega }}_{1,2}\hfill \\ \hfill & +0.6676671507{\mathsf{\Omega }}_{1,1}+0.3755627723{\mathsf{\Omega }}_{1,0}=0,\hfill \end{array}$

(35)$\begin{array}{cccc}\hfill & {\mathsf{\Omega }}_{1,0}=2.520901606,\hfill & \hfill {\mathsf{\Omega }}_{1,1}& =1.151887338,\hfill \\ \hfill & {\mathsf{\Omega }}_{1,2}=0.2747939421,\hfill & \hfill {\mathsf{\Omega }}_{1,3}& =-0.1007084772e^{-1},\hfill \\ \hfill & {\mathsf{\Omega }}_{1,4}=0.104275928e^{-2},\hfill & \hfill {\mathsf{\Omega }}_{1,5}& =-0.821281085e^{-3},\hfill \\ \hfill & {\mathsf{\Omega }}_{1,6}=0.159339626e^{-3},\hfill & \hfill {\mathsf{\Omega }}_{1,7}& =-0.4786732061e^{-4},\hfill \\ \hfill & {\mathsf{\Omega }}_{1,8}=0.3607728333e^{-5},\hfill & \hfill {\mathsf{\Omega }}_{1,9}& =-7.497331\times {10}^{-7}.\hfill \end{array}$

Through the utilization of the Equation (35) values in Equation (23), we derive the solution in the form of a series,

(36)$\begin{array}{cc}\hfill & 4.2\times {10}^{-10}x-0.1476247376x^9+0.8419045016x^8-2.111385138x^7+3.070620042x^6\hfill \\ \hfill & -2.869440800x^5+1.673118691x^4-0.8135601040x^3+3.783300440x^2+0.9999999990.\hfill \end{array}$

6. Discussion

All the numerical solutions obtained by the Hermite wavelet method and the algorithm were developed using MAPLE-17 software. In this section, we briefly discuss the tables and graphs obtained by solving the fractional-order Bagley-Torvik equation using the Hermite wavelet method. This will help us understand how accurate and efficient this method is. Table 1, Table 2 and Table 3 show the exact solutions and solutions obtained by the HWM method for $\alpha =1.06$, $\alpha =1.07$ and $\alpha =1.08$ respectively, while Table 4 visualizes the exact solutions and the error that occurs in the solution obtained using the HWM method with $\alpha =1.08$ and considering Example 1. Table 5 visualizes the HWM and analytical solutions with $\alpha =01.18$ by considering Example 2. Table 6 presents the error analysis of the HWM method with the FTM method by considering Example 2 and shows that the HWM method has a minimum error. The graphs visualize how closely the numerical solution coincides with the actual solution and compare it with other techniques. They also show how changing the fractional order affects the solution’s behaviour. Figure 1, Figure 2 and Figure 3 show the exact solutions and solutions obtained by the HWM method for $\alpha =1.06$, $\alpha =1.07$ and $\alpha =1.08$, respectively, while Figure 4 visualizes the exact solutions and the error that occurs in the HWM method solution, for $\alpha =1.08$ by considering example, 1. Figure 5 shows the simulation of an absolute error occurring in the SCOM method and HWM method, for example, 1. Figure 6 and Figure 7 visualize the HWM solutions for $\alpha =1.18$ and $\alpha =1.2$ respectively, with analytical solution for Example 2. Figure 8 presents the error analysis of the HWM method with the FTM method for Example 2 and shows that the HWM method has a minimum error. The error analysis in the graphs highlights that the Hermite wavelet method converges quickly and requires fewer calculations, making it a powerful tool for solving complex fractional equations. These visual results confirm that this method is reliable and effective for handling such problems. All the computations performed with the help of Maple software for obtaining the numerical solution, provides tables and graph analysis.

(37)$\begin{array}{c}\hfill z^{\left(2\right)}\left(y\right)+{\displaystyle \frac{1}{2}}{D}^{{\displaystyle \frac{2}{3}}}\left(y\right)+z\left(y\right)=2,0<y<1,\end{array}$

(38)$\begin{array}{c}\hfill z\left(0\right)=1,z\left(1\right)=2,\end{array}$

The exact solution to (37) is given by

(39)$z=1+y.$

Making use of the Hermite wavelet procedure, we have to approximate Equations (37) and (38). Consider

$D^{\alpha }\left(y\right)={\displaystyle \frac{1}{\Gamma (l-\alpha )}}{\displaystyle \frac{d^l}{d{y}^l}}{\int }_0^y{\displaystyle \frac{1+z}{{(y-z)}^{(\alpha -l+1)}}}dz,$

For r = 1 and J = 15, we shorten the series Equation (11) in order to approximate $z\left(y\right)$ using HWM.

(40)$z\left(y\right)\approx \sum _{j=0}^{15-1}{\mathsf{\Omega }}_{1,j}\phi \left(y\right)={\mathsf{\Omega }}^T\phi \left(y\right),$

(41)${\phi }_{s,j}\left(y\right)=\left\{\begin{array}{cc}\frac{2^{\frac{r+1}{2}}}{\surd \pi }{\aleph }_j(2^{r}y-2s+1),\hfill & \frac{s-1}{2^{r-1}}\le y<{\displaystyle \frac{s}{2^{r-1}}},\hfill \\ 0,\hfill & otherwise,\hfill \end{array}\right.$

Where $\mathsf{\Omega }$ and $\phi \left(y\right)$ are matrices. respectively. As the number of constants in Equation (40) are 15, but the number of equations formed in the algorithm are only two, which can be found by the boundary conditions. These conditions are not sufficient to obtain the numerical solution where we need more constants. For this, we use some collocation points from which we obtain more equations that will be beneficial to solve the system of equations. The collocation points will be generated by the following formulae, which are used in the Hermite algorithm. Then. we have to collocate Equation (13) by limiting the points of the following sequence, to obtain the remaining 13 equations,

(42)$\left\{y_i\right\}=\left\{{\displaystyle \frac{1}{2}}(1+cos{\displaystyle \frac{(i-1)\pi }{9}})\right\},$

We then determine the values of the unknown constants by simultaneously solving these equations. The needed series equation is obtained by substituting the values of unknown constants into the consider series Equation (40).

(43)$\begin{array}{cc}\hfill z\left(y\right)=& 8.349957829x^{15}-28.01273320x^{14}-62.4172040x^{13}+567.3871825x^{12}-1615.713740x^{11}\hfill \\ \hfill & +2724.785409x^{10}-3123.832510x^9+2579.378907x^8-1578.884043x^7+726.946224x^6\hfill \\ \hfill & -253.359801x^5+67.046544x^4-13.7744135x^3+2.27398017x^2+0.9999999892\hfill \\ \hfill & +0.8262512997x.\hfill \end{array}$

The tables and graphs show a comparison of the exact solution and numerical solution.

7. Conclusions

This work develops a numerical technique for solving the BTE equation. The foundation of this approach is the successive approximation of the Hermite polynomial. By using the Hermite technique, the provided equation is transformed into a system of algebraic equations using Reiman Liovillie derivatives. Next, the Hermite algorithm was used in the Maple to compute the system of equations. Through this process, an approximate solution was derived and then compared with the exact solutions and other numerical techniques. By comparing our findings to other numerical approaches, we found that it is more effective and efficient based on error analysis.

Footnotes

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Figure 1. Numerical simulation for comparison between the exact solution and approximate solution for Example (2).

Figure 2. Numerical simulation for comparison between the exact solution and approximate solution for [Forumla omitted. See PDF.] for Example (2).

Figure 3. Numerical simulation for comparison between the exact solution and approximate solution for [Forumla omitted. See PDF.] and J=10 for Example (2).

Figure 4. Numerical simulation for comparison between the exact solution and error for [Forumla omitted. See PDF.] and J = 10 for Example (2).

Figure 5. Numerical simulation of BTE for absolute error using HWM with SCOM [35] for [Forumla omitted. See PDF.] and J = 10 for Example (2).

Figure 6. Numerical simulation of BTE for the exact solution and approximate solution using HWM for [Forumla omitted. See PDF.] and J = 15 for Example (2).

Figure 7. Numerical Simulation of BTE for the exact solution and approximate solution using HWM for [Forumla omitted. See PDF.] and J = 15 for Example (2). The orange dash lines in the graph show the approximate solutions obtained by HWM method and the purple dashes line visualize the analytical solutions in the figure.

Figure 8. Numerical simulation error analysis of BTE for the numerical solution using HWM with FTM for Example (2).

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