An Intelligence Computational Approach for the Fractional 4D Chaotic Financial Model

: The main purpose of the study is to present a numerical approach to investigate the numerical performances of the fractional 4-D chaotic financial system using a stochastic procedure. The stochastic procedures mainly depend on the combination of the artificial neural network (ANNs) along with the Levenberg-Marquardt Backpropagation (LMB) i


Introduction
The characteristics based on the dynamics of the system provides the interest of many scientists with its complex and important features.This behavior depends directly on the parameters, which are used to describe the physical phenomenon as well as the sensitivity of the dynamical models with slight change in the initial conditions [1].These dynamical systems can be widened to have several applications in various branches of science, engineering, and Eco physics.This terminology has been introduced and invented by those researchers who are working in the field of simulating financial and economic systems.This branch deals with some of the physical theories and real-world applications and techniques applied to financial fields [2][3][4].The memory effects in the study based on these financial models play an important role to understand these complex systems [5].In economy, the memory effects can be represented by a fractional order term to describe the model, and hence the role of the fractional calculus has its presence in this part.The fact that integer differentiations can be considered as a local operator, cannot be used to describe these financial systems, and become more realistic through the fractional models to describe the effect of memory on these models.
The concept of fractional calculus has been first introduced by two famous scientists Riemann et al. [6][7][8][9].Since then, many definitions based on the fractional operators have been used to simulate different phenomena, including the Caputo fractional operator, Rieman Liouville operator, and others [10].Each of these definitions has its properties and drawbacks, which may suit some models more than others.The definition of the fractional operators in terms of Caputo and Riemann Liouville has singular kernels and stasis as some of the exceptional criteria including the index law which promote them to be one of the best definitions in fractional calculus.Nowadays, there has been another rising definition of fractional operators based on the exponential kernels and the generalized Mittag -Lefler functions [11] and also by Atangana et al. (AB) [12].Several problems have been simulated through different definitions as described.For example, the Caputo fractional derivative has been used to describe the mosaic disease with some optimal control by Vellappandi et al. [13].A delayed model describing the vector-borne plant epidemic has been studied by Kumar et al. [14] to better understand the behavior of such models.The AB definition can be used to describe the physical phenomenon with its property of preserving information over some time [15].Recently, there have been many works on the definition of Mittag-Leffler with nonsingular Kernel and their possible applications with different forms.Singh [16] expanded the definition of the Mittag-Leffler law for understanding the rumor spreading through the fractional dynamical model in social networks.In biology, the application of the Mittag-Leffler laws was studied by Qureshi et al. [17] for simulating the blood ethanol concentration leading to some new insight into its dynamics.The smoking dynamic model was investigated by using some of the definitions by Uçar et al. [18].This study aims to present a new technique for solving a fractional order optimal 4D chaotic financial model under some Mittag-Leffler laws in the following form as: CMC, 2023, vol.74, no.2

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where C 0 D α t is defined as the Caputo fractional derivative and α are the fractional order that is taken between 0 and 1. β, γ , ω, ℵ and M are all positive parameters in the financial model (1).The model (1) represents a more realistic form rather than the integer model, since it is known in financial models that surplus investments are some the examples of investment market contradictions.These points are of a major effect on the interest rates and control input variables.In addition, this flaw is also affected by the irregularity subsequent from the organizational adjustment of the prices.This was the main motivation for using the fractional-order model and trying to adapt some new states of the artificial neural network (ANNs).
Recently, ANNs have been considered one of the most important techniques that have been used to find the solutions to the complex problems.Due to the wide real-life applications in different areas of science and engineering, scientists have been striving for expanding the applications of these techniques along with different properties.For example, El-Mahelawi et al. [19] investigated the solution of some model classifications using the tumors.Sabir et al. [20] adapted the Morlet wavelet neural network for solving a class of nonlinear system to simulate the nervous stomach system.Also, biology has its share of the simulations done with the aid of these methods.For example, the influenza disease model is one of the models that have been solved using a novel design of the ANNs accompanied by the Levenberg-Marquardt backpropagation [21].COVID-19 pandemic is one of the most important models that have been solved by Umar et al. in [22].In addition, Umar et al. [23] proposed a computational framework applying the same algorithm for solving the SIR model, which provides better understanding of dengue fever.For more details regarding the ANNs-LMB method and its applications, the reader may refer to [24][25][26][27][28] and references therein.This work aims to simulate the nonlinear 4-D chaotic financial model represented in the system (1) to gain more insight into the dynamics of this important model.The ANNs-LMB technique consists of merging the regular artificial neural networks (ANNs) along with the Levenberg-Marquardt backpropagation (LMB), resulting as a new technique.The proposed algorithm is a promising one since it can deal with different complex problems.The main concept of this algorithm is based on the samples of training, testing and verification samples to get the obtained solutions by using the accurate and efficient technique.This method proves to be a valuable key player in stimulating real p = life phenomena, e.g., the simulation of the heat distribution in the human head and simulated using this technique as in [29].Also, ANNs procedures have been used to solve the third kind of Emden-Fowler model in [30] by Sabir et al.A new solver based on the Meyer fractional neuro-evolution computing method for solving a doubly singular fractional kind of systems [31].Few other applications of the stochastic methods can be found [32][33][34][35][36][37] in references therein.
The novelty of the proposed technique can be summarized in the following few points: • A model of the 4-D chaotic financial model under some Mittag-Leffler nature and have the benefit of a more realistic application.• The proposed technique is used to solve system (1) with the combination of the ANNs-LMB method.
• The correction of the proposed scheme is observed through the comparison of the proposed and reference solutions.
• The absolute error is provided in good measure, which authenticates the proposed solver is an accurate and reliable to solve the fractional form of the 4-D chaotic financial problem.• The combined features of the ANNs with the LMB enhance the accuracy of the obtained results in terms of error for solving the 4-D chaotic financial problem.
The organization of the paper is as follows: Section 2 gives the details of the proposed ANNs-LMB algorithm.The numerical validation of the proposed technique is examined in Section 3. Concluding remarks of the study are illustrated in Section 4.

Methodology: ANNs-LMB
This section is illustrated the main steps for the proposed technique named the ANNs-LMB method.This method shall be used to solve the 4-D chaotic financial model represented by Eq. ( 1) along with their initial conditions.The main steps of the proposed algorithm may be summarized in the following few points as: 1-A numerical method with stochastic features based on the ANNs-LMB technique will be used to solve the model (1).2-The effectiveness and robustness of the proposed algorithm will be tested for solving the 4-D chaotic model through the application of the proposed technique.
These main steps are illustrated in Fig. 1 with the action of the multilayer procedure where the method is based on the ANNs-LMB stochastic solver.Fig. 1 demonstrates the use of the ANNs-LMB method for simulating the data and compared it to the reference solution.

Numerical Validation
This section is devoted to validating the performance of the proposed technique by using the numerical results.The performance of the method in solving the problem (1) is tested with three different cases of the fractional terms.The mathematical representations of the system (1) are simulated for the setup of parameters in the following form as: Three cases are investigated for the solution of the system (2) with different values of the fractional order α = 0.6, α = 0.7, and 0.8, respectively.The complete results have been accomplished using the ANNs-LMB technique with a training value of 73%, testing of 15%, and certification of 12% to solve the model (2).The obtained numerical performances using 14 neurons for using the proposed technique is drawn in Fig. 2.

Methodology Stochastic Framework
Construction of a multi-layer procedure by using the ANNs-LMB solver for the 4-D chaotic financial model under some Mittag-Leffler nature Reference Solutions A dataset is designed by using the computing stochastic ANNs -LMB method for solving the 4 -D chaotic financial model under some Mittag -Leffler nature and have the benefit of the more realistic application Mathematical Model    2).These fitting curves are plotted and these results are based on the comparative performance of the obtained results through the application of the proposed method.These plots are drawn based on the EH results for approximating model ( 2) and these values lie in 4.20 × 10 −05 for the case I, 1.70 × 10 −06 for case II and 2.75 × 10 −05 for case III.The verification of the performance of the proposed ANNs-LMB technique is measured through some regression performance measures that can be seen in Figs.5-7 for cases I, II, and III, respectively.The correlation measures indicate that the regression performance is calculated as one, which proves the perfect model.Fig. 8 provides a comparison of the results obtained for different three cases with some reference results that ensure that the provided method is effective.The AE using the comparative are drawn in Fig. 9 for the 4-D chaotic model.One can find from these data and plots that the acquired results and reference solutions are overlapping for each case of the 4-D chaotic system.The results matching signify the perfection, significance, and precision of the scheme.In addition, the value of the AE for the case I and II is around 10 −05 and around 10 −06 for case III.The current study aims to investigate the numerical simulation of a 4-D chaotic financial system under some Mittag-Leffler laws using a combination of the artificial neural network and the Levenberg-Marquardt backpropagation techniques named the ANNs-LMB technique.The fractional order derivatives have been implemented to perform more realistic solutions of the 4-D chaotic financial system.The computational scheme is applied for three variations of the fractional kinds of models using different fractional values.The statics proportions have been applied as 73%, 15%, and 12% for training, testing, and certification for the 4-D chaotic model.The number of neurons used is 14 to solve the model.The numerical outcomes for the nonlinear fractional chaotic system are obtained by using the ANNs-LMB technique in order to reduce the MSE for the acquired approximate solutions.To ensure the reliability, and effectiveness of the scheme, the numerical measure is plotted and compared to a reference solution.The absolute error is provided in good ranges, which shows the competence of the proposed stochastic solver.The performance of the technique is witnessed to be ideal for the proposed model in terms of precision and accuracy.
Achieved performances through the ANNs-LMB based on the Fitness, STs, MSE, EHs, correlation and regression measures to solve the 4-D chaotic financial model under some Mittag-Leffler nature and have the benefit of the more realistic application AE The values of the AE are presented using the comparison of the obtained results through ANNs-LMB and the reference outcomes to solve the 4-D chaotic financial model under some Mittag-Leffler nature and have the benefit of the more realistic application

Figure 1 :
Figure 1: Workflow illustrations of the proposed method for the fractional-order chaotic financial model

Figure 2 :
Figure 2: Schematic diagram for the proposed technique to solve the model (2)