key: cord-0805015-0jaa6h8g authors: Sabir, Zulqurnain; Umar, Muhammad; Shah, Ghulam Mujtaba; Wahab, Hafiz Abdul; Sánchez, Yolanda Guerrero title: Competency of Neural Networks for the Numerical Treatment of Nonlinear Host-Vector-Predator Model date: 2021-10-04 journal: Comput Math Methods Med DOI: 10.1155/2021/2536720 sha: eb09bd442fb2fae3280dfb0e8320c53cf1e37e0c doc_id: 805015 cord_uid: 0jaa6h8g The aim of this work is to introduce a stochastic solver based on the Levenberg-Marquardt backpropagation neural networks (LMBNNs) for the nonlinear host-vector-predator model. The nonlinear host-vector-predator model is dependent upon five classes, susceptible/infected populations of host plant, susceptible/infected vectors population, and population of predator. The numerical performances through the LMBNN solver are observed for three different types of the nonlinear host-vector-predator model using the authentication, testing, sample data, and training. The proportions of these data are chosen as a larger part, i.e., 80% for training and 10% for validation and testing, respectively. The nonlinear host-vector-predator model is numerically treated through the LMBNNs, and comparative investigations have been performed using the reference solutions. The obtained results of the model are presented using the LMBNNs to reduce the mean square error (MSE). For the competence, exactness, consistency, and efficacy of the LMBNNs, the numerical results using the proportional measures through the MSE, error histograms (EHs), and regression/correlation are performed. Microorganisms create many diseases in plants by means of nematode worms, viruses, protozoan fungi, and bacteria that spread from the vectors. A variety of schemes have been implemented to control the disease spread in plants called predators as a biological agent [1] . For the disease spread in plants, the mathematical modeling has a vital part in retrospectively to investigate the dynamics of the vector-bornebased plant diseases [2] . Jeger et al. discussed the mathematical plant model to understand the disease dynamics and virus transmission in 2011 [3] . After a period of one year, Jeger et al. created a compartmentalized system to consider the dynamical vector population to examine the effects of viral spread [4] . Rida formulated the arrangement in 2016 based on the plant fractions of disease, which are transmitted through the vectors [5] . Muryawi analyzed and formulated a dynamic nonlinear system to plant vector-borne spreading diseases from insects in 2017 [6] . Moreover, he established the deterministic nonlinear system and simulated with the values of the hypothetical parameters. Several scientists have formulated epidemiological systems for single plant/vector type to find the host-based plant through two diseases. Khan in 2018 established the S H − E H − I H − S V − E V − I V system, which designates the pine wilt disease-based dynamics [7] . Bokil in 2019 designed a vector virus of the plant system including mud planting policy [8] . Donnelly developed a simple system in 2020 to describe the dynamic population form of vector components [9] . Anggriani et al. designed a compartmental deterministic mathematical system based on the vector-borne to regulate the effects of insect vectors of the rice plant virus. The same year, the SPEIR system is discovered for the disease spread dynamics in the plants to provide the rouging, preventive, curative, and replanting [10] . Mathematical systems indicate various complexities, which rely on the problem characteristics. Few of the systems require high complexity cost especially for simulation, when a complicated or stiff system is considered. A number of numerical formulation schemes have been used by the researcher's community to solve the system of nonlinear equations. Some of them are the differential transformation approach [11] , Adams numerical approach [12] , variational iteration method [13] , Caputo fractional difference scheme [14] , and many more [15] [16] [17] [18] [19] . This study is related to solve one-dimensional hostvector predator system by introducing a stochastic numerical solver based on the Levenberg-Marquardt backpropagation neural networks (LMBNNs). Suryaningrat et al. [20] discovered the host-vector-based system to assume that a predator works as a biological mediator, which use disease vectors through plants. The nonlinear host-vector-predator model is dependent upon five classes. The general system of the nonlinear host-vector-predator equations along with initial conditions (ICs) is given as [2] The state variables for each class of the nonlinear hostvector-predator system with the appropriate selections are presented in Table 1 as This study is associated to introduce a stochastic solver based on the Levenberg-Marquardt backpropagation neural networks (LMBNNs) for the nonlinear host-vector-predator system. The numerical performances of all the classes of the nonlinear host-vector-predator model are presented through the LMBNN solver using the authentication, testing, sample data, and training. The proportions of these data are chosen a larger part, i.e., 80% for training and 10% for validation and testing, respectively. The stochastic solvers have been implemented to exploit a variety of applications in the field of biological, singular, functional, higher order, nonlinear, and fractional differential models [21] [22] [23] . However, stochastic design of LMBNNs has never been explored to solve the nonlinear host-vector-predator model. Few well-known applications of the numerical stochastic solvers are COVID-19 system [24] , nonlinear higher order system [25] , Thomas-Fermi equation [26] , differential form of the fractional models [27] , dengue fever nonlinear system [28] , periodic singular models [29] , a multisingular system [30] , and functional models [31] [32] [33] . These motivate submissions impressed the authors to solve the nonlinear host-vector-predator model using a robust, consistent, precise, and reliable platform through the LMBNN operators. Some novel features of the present work are provided as The paper is organized as follows: the numerical results are provided in Section II. The obtained numerical outcomes are presented in Section III. Concluding remarks and future research reports are provided in Section IV. In this section, the proposed LMBNNs are presented in two phases to solve all five classes of the nonlinear host-vectorpredator model. The detail of the necessary procedures of the LMBNNs along with the execution procedures of all five Figure 1 : Workflow diagram using the LMBNNs to solve the nonlinear host-vector-predator system. x 3 x k Activation function Computational and Mathematical Methods in Medicine classes of the nonlinear host-vector-predator system is also presented. Figure 1 indicates an appropriate optimization procedure using the LMBNNs for the multilayer actions. The proposed model is illustrated in Figure 2 for a single neuron. The LMBNN procedure is accomplished with "nftool" (Matlab's built-in command) based on the proportions of the data that are chosen as 80% for training and10% for validation and testing, respectively. The numerical results are presented using the LMBNNs for three cases of the nonlinear host-vector-predator model based on its five categories along with the mathematical form that is provided as Case 1: suppose a nonlinear host-vector-predator model is written as The numerical performances are achieved to solve all five classes of the nonlinear host-vector-predator model using the LMBNNs with input [0,1] and step size 0.01. The designed LMBNNs using the proportions of these data are chosen as 80% for training and 10% for validation and testing, respectively. The number of neurons is taken as 9 in this study for the nonlinear host-vector-predator system. The obtained values through the LMBNNs to solve each class of the nonlinear host-vector-predator system are provided in Figure 3 . The illustrations of the LMBNNs to solve the nonlinear host-vector-predator system are provided in indicate the regression investigations. It is observed that the correlation values are found 1 for each case of the hostvector-predator system that is a case of the perfect model. The testing, authentication, and training plots represent the precision and accuracy of the LMBNNs to solve each class of the nonlinear host-vector-predator model. Additionally, the convergence-based MSE measures are authorized through training, epochs, verification, backpropagationbased performances, testing, and complexity measures that are shown in Table 2 to solve the nonlinear host-vectorpredator system. The comparative investigations are illustrated in Figures 9 and 10 for each class of the nonlinear hostvector-predator system. The outcomes from the classes "Sh," "Ih," "Sv," "Iv," and "P" based on the nonlinear hostvector-predator model using the LMBNNs are plotted in subfigures 9(a)-(e). The exact matching of the results (obtained and reference) labels the exactness and precision of the LMBNNs to solve all five classes of the nonlinear host-vector-predator system. The performances of AE are plotted to solve each class of the system. The AE of the classes "Sh," "Ih," "Sv," "Iv," and "P" based on the nonlinear host-vector-predator model using the LMBNNs are plotted in subfigures 9(a)-(e). Figure 9 (a) depicts the AE for the class S h that lie around 10 -06 to 10 -09 , 10 -06 to 10 -10 , and 10 -06 to 10 -07 for cases 1, 2, and 3, respectively. In Figure 9 (b), it is observed that the AE for the category I h lie around 10 -05 to 10 -09 , 10 -07 to 10 -10 , and 10 -05 to 10 -07 for cases 1, 2, and 3, respectively. In Figure 9 (c), one can find the AE for the class S v that lie around 10 -04 to 10 -06 , 10 -05 to 10 -07 , and 10 -05 to 10 -06 for cases 1, 2, and 3, respectively. In Figure 9 (d), it is found the AE for the class S v lie around 10 -05 to 10 -08 and 10 -06 to 10 -08 for cases 2 and 3, respectively. In Figure 9 (e), it is noticed that the AE for the class P lie around 10 -05 to 10 -06 , 10 -05 to 10 -07 , and 10 -06 to 10 -07 for cases 1, 2, and 3. This close matching of the solutions indicates the exactness and correctness of the LMBNNs to solve each class of the nonlinear host-vector-predator model. In this study, an introduction of the stochastic solver based on the Levenberg-Marquardt backpropagation neural networks is presented for the nonlinear host-vector-predator model. This nonlinear system is dependent upon five classes named as susceptible/infected populations of host plant, susceptible/infected vectors population, and population of predator. Three different cases of the nonlinear hostvector-predator model based on the prediction rate have been taken and numerically performed through the LMBNN solver using the authentication, testing, sample data, and training. These data proportions are selected as a major part for training i.e., 80% and 10% and 10% for validation and testing, respectively. The overlapping of the numerical solutions with the reference results is performed, and the AE is 9 Computational and Mathematical Methods in Medicine found very accurate that is around 10 -06 to 10 -10 for each class of the nonlinear host-vector-predator system. The obtained result performances of the system are presented using the LMBNNs to reduce the mean square error (MSE). For the competence, exactness, consistency, and efficacy of the LMBNNs, the numerical results using the proportional measures through the MSE, error histograms (EHs), and regression/correlation are also performed. One can find that the proposed LMBNNs is stable and performs as an accurate solver to solve the nonlinear stiff system of equations. In future, the proposed LMBNNs can be implanted to find the numerical solutions of the fractional order system [34] [35] [36] [37] [38] . 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The authors declare that they have no conflicts of interest.