Stochastic numerical approach for solving second order nonlinear singular functional differential equation

“…Repeat the process by using the equations (20) and (25) for N � 6 and k � 0, 1, and 2. e solution of the obtained linear algebraic equations system is given as…”

“…e parameters τ i (i � 1, 2, 3, 4) and α, β, a, b, and c are the real constant values. e idea of the above model is achieved by extending the work of Sabir et al [25] that is used to explain the nonlinear singular FDEs of second order. For the verification and correctness of the designed MS-FDEs model, three different examples have been modeled and numerically solved by using the well-known differential transformation (DT) scheme, and the obtained numerical outcomes of DTscheme are compared with the exact solutions.…”

“…Some major key factors of the present study are summarized as follows: e mathematical modeled form of the third-order nonlinear MS-FDEs is presented successfully by extending the work of Sabir et al [25] e designed nonlinear MS-FDEs based on the designed model are addressed numerically by using the famous DT scheme.…”

On a New Model Based on Third-Order Nonlinear Multisingular Functional Differential Equations

“…Repeat the process by using the equations (20) and (25) for N � 6 and k � 0, 1, and 2. e solution of the obtained linear algebraic equations system is given as…”

“…e parameters τ i (i � 1, 2, 3, 4) and α, β, a, b, and c are the real constant values. e idea of the above model is achieved by extending the work of Sabir et al [25] that is used to explain the nonlinear singular FDEs of second order. For the verification and correctness of the designed MS-FDEs model, three different examples have been modeled and numerically solved by using the well-known differential transformation (DT) scheme, and the obtained numerical outcomes of DTscheme are compared with the exact solutions.…”

“…Some major key factors of the present study are summarized as follows: e mathematical modeled form of the third-order nonlinear MS-FDEs is presented successfully by extending the work of Sabir et al [25] e designed nonlinear MS-FDEs based on the designed model are addressed numerically by using the famous DT scheme.…”

On a New Model Based on Third-Order Nonlinear Multisingular Functional Differential Equations

“…Researchers have widely studied the meta-heuristic based computing numerical approaches along with the neural network's strength for solving the linear/non-linear mathematical models [17][18][19][20][21][22][23][24]. Some recent applications of heuristic computing are corneal models for eye surgery [25], the non-linear Riccati system [26], the Bagley-Torvik system [27], non-linear systems of Bratu type [17], prey-predator non-linear models [28], nonlinear reactive transport models [29], non-linear optics models [30], non-linear singular functional differential models [31], singular non-linear systems arising in atomic physics [32], non-linear doubly singular systems [33], nanofluidic systems [34], micropolar fluid flow [35], the heartbeat model [36], the singular Lane-Emden equation based model [37], the heat conduction model of the human head [38], non-linear electric circuit models [39], finance [40], and mathematical models in Bioinformatics [41,42]. These influences proved the value, worth and consequence of the stochastic solvers based on robustness, accuracy and convergence.…”

A Neuro-Swarming Intelligence-Based Computing for Second Order Singular Periodic Non-linear Boundary Value Problems

“…e differential model has a broad application in many phenomena as in [12][13][14]. Recently, nonlinear fractional differential equations (NLFDEs) show significantly in engineering and applications of other sciences, for example, electrochemistry, physics, electromagnetics, and signal data processing [15][16][17][18][19][20][21][22].…”

Analytical Solutions for Nonlinear Dispersive Physical Model