Schistosomiasis disease (SD) is a parasitic disease produced by worms of the species Schistosoma. Schistosomiasis was treated for approximately 206 million people in 2016. However, the observed number of people expected to treat in 2016 was 89.2 million [1]. This disease instigated by tapeworms, which are members of the monophyletic Platyhelminthes and the species Schistosoma [2–4]. In 1905, a doctor in Changde discovered Schistosoma camellia eggs on an 18-year-old farm worker. The life cycle of schistosomiasis is complicated. It consists primarily of two rapacious host stages, human and larva, as well as two free pelagic stages, cercariae and miracidia. Roundworms in host organism eggs, which may pass through the large intestine and into the eco system with the faces. After entering fresh water, the eggs initiate to hatch and grow into miracidia. The unrestricted miracidia then infect the snail intermediate hosts, which is known as the larval development. The snails produce a large number of cercariae and release them into the water via asexual reproduction. Free-moving cercariae can damage the skin and enter the bloodstream, where they sophisticated into adults when humans come into contact with water.

Schistosomiasis mathematical analysis is not new, but it is typically expressed in the form of boundary value problems. Several researchers have used a deterministic approach to develop new schistosomiasis approaches or modify existing ones [5–7]. Fractional calculus has been widely used in real-world problems in recent years to describe genetic properties, energy dissipation effects, cognition, and harm structures. The Riemann–Liouville (RL) and Caputo fractional operators are excellent definitions of fractional differential equations, which are defined as the complexity of a given polynomial function/its derivative and the heat dissipation feature as a kernel [8]. These operators are non-local, according to this definition. The singularity caused by the energy decay kernel function on the other hand, includes multiple considerable computational difficulties necessitating the introduction of numerical solutions.

Fractional calculus (FC) was invented in the time of Newton, but it has recently piqued the interest of many academics. Over the last thirty years, the most fascinating leaps in industry sectors have been discovered within the structure of FC. The idea of the fractional derivative has been modernized due to the complexities affiliated with the characteristic of inhomogeneity. The behavior of multifaceted media with a diffusion process can be captured using fractional differential operators. It has been a very valuable tool, but many problems can now be demonstrated more helpfully and precisely using ordinary differential equations of any order. Many scholars began to work on simplistic calculus to reveal their points of view while analyzing a wide range of complex phenomena as a result of the rapid development of computational techniques with computer software systems. Many senior researchers proposed various concepts for fractional-order and integral operators, which arranged the foundation [9–14]. Many researchers have recently considered fractional calculus to be a more efficient approach than integer-order calculus when examining real-world problems suggested using mathematical models. For instance in [15], authors take into account the different derivative identified with the assistance of the non-singular operative in order to examine the fibroid surveillance model in [16], a new fractional concept along with a control scheme for the infection of dengue infection has been efficiently and successfully highlighted in [17], researchers consider the computational method in order to typify the efficiency while an For instance in [15], authors take into account the different derivative identified with the assistance of the non-singular operative in order to examine the fibroid surveillance model in [16], a new fractional concept along with a control scheme for the infection of dengue infection has been efficiently and successfully highlighted in [17], researchers consider the computational method in order to typify the efficiency while analyzing blood sugar levels and infectious diseases. The mathematical and analytical results for the equations highlighting these models play an important role in depicting the nature of nonlinear problems in associated fields of science [18–30].

Recent advances in fractional calculus (FC) theory have resulted in the creation of two notable operators, Caputo–Fabrizio and Atangana–Baleanu. The new derivatives mentioned above have non-singular kernels and do not use energy-distribution. The Atangana–Baleanu operator is mainly focused on the simple Mittag-Leffler method, which has powerful forces because its diffusional effects are collaborations with good assumptions. The Caputo–Fabrizio estimation is also based on exponential law, which can be found in a variety of natural phenomena and has a fusion effect with numerical depiction. These operators have demonstrated that they are the future for demonstrating a variety of scientific progressions such as turbulent theory, life processes, heat flux problems, operations research, and financial problems, among others [31–38].

This research is related to the development of a fractional order mathematical model focused on the evolution of the schistosomiasis disease. The use of fractional order derivatives is implemented to observe more precise performances of the mathematical equation. The novel fractional order mathematical model solutions will be described using stochastic artificial neural network (SANN) processes in conjunction with Levenberg-Marquardt backpropagation (LMBP), i.e., ANN-LMBP.

To solve the dynamic behavior of the schistosomiasis disease, the ANN system is proposed effectively using LMBP optimization processes.

The paper is systematized as: Section 2 demonstrates the configuration of the fractional order mathematical equation, Section 3 contains the stochastic contributions, Section 4 is created on ANN-LMBP method, Section 5 is intended using simulation procedures, and the final part contains concluding remarks.

The model defines the total humanity at time ε, symbolized by N(ε), into susceptible persons who are uninfected with schistosomiasis W(ε), those who have been infected with schistosomiasis A(ε), and those who have healed from the kind of disease infection Q(ε). As a result, the whole social population is N=W+A+Q. Furthermore, N1 divides the total snail populations into vulnerable snails that uninfected with schistosomiasis U and those that have been infested with schistosomiasis infectious V. This indicates that N1=U+V represents the total vector population. The following non-linear ordinary differential equations are derived from the interlinkages with the compartments.(1){dW(ε)dε=λ1−α1SW(ε)+γQ(ε)−β1W(ε),W0=k1,dA(ε)dε=α1SW(ε)−(β1+δ)A(ε),A0=k2,dQ(ε)dε=δ−(γ+β1)Q(ε),Q0=k3,dE(ε)dε=λ2−α2A(ε)E(ε)−β2E(ε),E0=k4,dS(ε)dε=α2A(ε)E(ε)−β2S(ε).S0=k5.

Tab. 1 contains characterizations of the mathematical model built on the schistosomiasis disease of each parameter.

The current research aims to provide numerical simulations of a fractional order mathematical formula based on the schistosomiasis disease using artificial intelligence (AI) and ANN-LMBP. The following is the structure of the fractional order mathematical model focused on the schistosomiasis disease:

(2){d(τ)W(ε)dε(τ)=λ1−α1SW(ε)+γQ(ε)−β1W(ε),W0=k1,d(τ)A(ε)dε(τ)=α1SW(ε)−(β1+δ)A(ε),A0=k2,d(τ)Q(ε)dε(τ)=δ−(γ+β1)Q(ε),Q0=k3,d(τ)E(ε)dε(τ)=λ2−α2A(ε)E(ε)−β2E(ε),E0=k4,d(τ)S(ε)dε(τ)=α2A(ε)E(ε)−β2S(ε).S0=k5.

In this system, τ is the fractional order derivative of the numerical schistosomiasis disease model.

The current section demonstrates the stochastic operator performances when solving the fractional order computational schistosomiasis disease model with ANN-LMBP. Stochastic software solvers have been examined in the literature to solve complicated, singular, and rigid systems [39–41]. Stochastic optimization algorithms have been recently used to perform simulation studies of nonlinear computer virus propagation model [42], infection control model [43], Lane-Emden systems [44], functional order approaches [45], and nonlinear dynamic HIV systems [46–49]. The purpose of this work is to review and develop a fractional order mathematical schistosomiasis disease model using mathematical procedures based on the ANN-LMBP. These references [50–54] present a number of applications-based time-fractional derivatives. The following are some novel characteristics of ANN-LMBP for solving the fractional order mathematical model:

A design fractional order and numerical solutions are introduced to tackle the mathematical schistosomiasis disease model.

This part of the study describes the proposed ANN-LMBP method for presenting the numerical schistosomiasis disease model solutions. The proposed ANN-LMBP scheme is introduced in two stages: the substantial performances of the ANN-LMBP method and the operational plans for solving the mathematical schistosomiasis model using the ANN-LMBP method. The significant operator performances-based L-MBNNs technique is provided.

The designed approach for solving the nonlinear fractional differential model is displayed in Fig. 1 and is based on the number of layer optimization procedures of the ANN-LMBP method. This study statics performances are 78 percent, 11 percent, and 11 percent for training, certification, and checking for tackling the fractional order computer simulation based on the schistosomiasis disease.

In this portion, three different variability of fractional order differential equations of the mathematical schistosomiasis disease model using ANN-LMBP are presented. Each type mathematical representation is as follows:

Case 1: Consider a fractional order mathematical model based on the schistosomiasis disease by using

τ=0.5, λ1=0.1, α1=0.12, β1=0.15, β2=0.18, δ=0.2, γ=0.23, λ2=0.23, α2=0.3, k1=0.1, k2=0.1, k3=0.3 and k4=0.4, k5=0.5.

(3){d(0.5)W(ε)dε(0.5)=0.1−0.12S(ε)W(ε)+0.23Q(ε)−0.15W(ε),W0=0.1,d(0.5)A(ε)dε(0.5)=0.12W(ε)S(ε)−(0.15+0.2)A(ε),A0=0.2,d(0.5)Q(ε)dε(0.5)=0.2−(0.23+0.15)Q(ε),Q0=0.3,d(0.5)E(ε)dε(0.5)=0.23−0.3A(ε)E(ε)−0.15E(ε),E0=0.4,d(0.5)S(ε)dε(0.5)=0.15A(ε)E(ε)−0.15S(ε).S0=0.5.

Case 2: Consider the use of a fractional order mathematical model based on the schistosomiasis disease τ=0.7, λ1=0.1, α1=0.12, β1=0.15, β2=0.18, δ=0.2, γ=0.23, λ2=0.23, α2=0.3, k1=0.1, k2=0.1, k3=0.3 and k4=0.4, k5=0.5.

(4){d(0.7)W(ε)dε(0.7)=0.1−0.12S(ε)W(ε)+0.23Q(ε)−0.15W(ε),W0=0.1,d(0.7)A(ε)dε(0.7)=0.12W(ε)S(ε)−(0.15+0.2)A(ε),A0=0.2,d(0.7)Q(ε)dε(0.7)=0.2−(0.23+0.15)Q(ε),Q0=0.3,d(0.7)E(ε)dε(0.7)=0.23−0.3A(ε)E(ε)−0.15E(ε),E0=0.4,d(0.7)S(ε)dε(0.7)=0.15A(ε)E(ε)−0.15S(ε).S0=0.5.

Case 3: Consider a fractional order mathematical model based on the schistosomiasis disease by using τ=0.9, λ1=0.1, α1=0.12, β1=0.15, β2=0.18, δ=0.2, γ=0.23, λ2=0.23, α2=0.3, k1=0.1, k2=0.1, k3=0.3 and k4=0.4, k5=0.5.

(5){d(0.9)W(ε)dε(0.9)=0.1−0.12S(ε)W(ε)+0.23Q(ε)−0.15W(ε),W0=0.1,d(0.9)A(ε)dε(0.9)=0.12W(ε)S(ε)−(0.15+0.2)A(ε),A0=0.2,d(0.9)Q(ε)dε(0.9)=0.2−(0.23+0.15)Q(ε),Q0=0.3,d(0.9)E(ε)dε(0.9)=0.23−0.3A(ε)E(ε)−0.15E(ε),E0=0.4,d(0.9)S(ε)dε(0.9)=0.15A(ε)E(ε)−0.15S(ε).S0=0.5.

The numerical representations using the outcomes of the fractional order mathematical schistosomiasis disease model are discussed utilizing ANN-LMBP method with 13 numbers of neurons and data selection as 78%, 11%, and 11% for training, certification, and testing, respectively. Fig. 2 depicts the structure of the input, hidden, and output neurons.

Figs. 3–5 show the fractional order mathematical schistosomiasis disease model developed using the ANN-LMBP method. The perfect EHs, curves, validations, and STs for the fractional order derivative mathematical schistosomiasis model are shown in Figs. 3 and 4. The best results of the fractional order mathematical schistosomiasis disease model (SDM) were obtained at epochs 38, 41, and 46, which were measured as 1.7573 × 10⁻¹⁰, 4.9824 × 10⁻¹⁰ and 8.6225 ×10⁻¹⁰. For the cases 1, 2 and 3, the gradient performances are 9.75 × 10⁻⁰⁸, 9.2105 × 10⁻⁰⁸, and 8.4198 × 10⁻⁰⁸. The graphical methodologies demonstrate the convergence of the ANN-LMBP method for solving the fractional order mathematical (SD) model. The profitability of the results and EHs for the fractional order mathematical schistosomiasis disease (SD) model using the ANN-LMBP technique is shown in Fig. 4. These result valuations compare the performances of the review literature and reference solutions. The training, testing, and substantiation results for the fractional order mathematical (SD) model are plotted. The second section of Fig. 4 discusses the EHs values, which are 1.97 ×10⁻⁰⁵, −3.6 × 10⁻⁰⁶, and 3.16 × 10⁻⁰⁷ for cases 1, 2, and 3. The correlation schemes for the fractional order mathematical (SDM) using the ANN-LMBP method are shown in Fig. 5. Using the ANN-LMBP method, the correlation for the fractional order mathematical (SD) model is found to be one. The precision of the ANN-LMBP method for the fractional order mathematical (SD) model is labelled by its training, testing, and substantiation accomplishments. Tab. 2 shows the MSE for the fractional order mathematical (SD) model by using ANN-LMBP method after verification, complexity, checking, training, generations, and backpropagation.

The correctness of the proposed ANN-LMBP method for the fractional order mathematical (SD) model is observed in Figs. 6 to 7 based on the result comparison and AE performances. The calculated form of the numerical solutions has been drawn to solve the nonlinear model using the ANN-LMBP method. The matching of the calculated and reference results has been illustrated in Fig. 6. These plots present the precision of the ANN-LMBP method for the fractional order mathematical schistosomiasis disease model. The performances of AE to solve the fractional order mathematical (SD) model using the stochastic paradigms are plotted in Fig. 7.

The AE is provided based on the not infected with schistosomiasis W(ε), infected with schistosomiasis A(ε), recovered from infection Q(ε), susceptible snail not afflicted with schistosomiasis disease E(ε) and susceptible snail afflicted with this disease S(ε). It is observed that the not infected with schistosomiasis W(ε) lie around 10⁻⁰⁴ to 10⁻⁰⁶, 10⁻⁰⁵ to 10⁻⁰⁷ and 10⁻⁰⁵ to 10⁻⁰⁷ for the case 1, 2 and 3. The AE for the people infected with schistosomiasis A(ε) lie around 10⁻⁰⁴ to 10⁻⁰⁴, 10⁻⁰⁵ to 10⁻⁰⁴ and 10⁻⁰⁵ to 10⁻⁰⁶ for the case 1, 2 and 3. The AE for the people recovered from infection Q(ε) found 10⁻⁰⁴ to 10⁻⁰⁴, 10⁻⁰⁵ to 10⁻⁰⁴ and 10⁻⁰⁵ to 10⁻⁰⁶ for the case 1, 2 and 3. Similarly, the AE for the behaviors E(ε)& S(ε) found 10⁻⁰⁴ to 10⁻⁰⁵, 10⁻⁰⁵ to 10⁻⁰⁵ and 10⁻⁰⁶ to 10⁻⁰⁷ for the case 1, 2 and 3. These best AE values represent the exactness of proposed ANN-LMBP method for the fractional order mathematical (SD) model.

In this presents study the numerical solutions of the fractional order mathematical model are presented based on the schistosomiasis disease. The goal of finding fractional order numerical solutions is to improve the accuracy of the mathematical model performance. The nonlinear mathematical system is divided into five dynamics, susceptible snail not infected with (SD) E(ε), susceptible snail afflicted with (SD) S(ε), not infected with schistosomiasis W(ε), recovered from infection Q(ε), and infected with schistosomiasis A(ε) order systems have never been used before by using the intended stochastic ANN-LMBP. It has been discovered that those who are not infected with schistosomiasis W(ε). To demonstrate the correctness of the ANN-LMBP method, numerical presentations of three different value parameters based on fractional order will be conducted. To solve the nonlinear fractional order system, thirteen neurons have been presented. This study statics performances are 78%, 11%, and 11% for training, certification, and testing for tackling the fractional order mathematical model based on schistosomiasis diseases. To determine the correctness of the ANN-LMBP method, the calculated values were compared to the Adams-Bashforth-Moulton. The MSE efficiency is reduced to locating numerical solutions of the ANN-LMBP technique for solving the fractional order derivative mathematical model based on the schistosomiasis disease. The ANN-LMBP method capability and dependability are demonstrated using numerical representations based on STs, EHs, MSE, correlation, and regression. The ANN-LMBP method achieves precision by using a fractional order mathematical model and comparing the obtained and reference results.

In future given methodology can be implemented to many fractional and integer order systems of utmost significance [55–65].