Learning Time Delay Systems with Neural Ordinary Differential Equations

“…dy t ry t cy qt dt =+ (1.3) In this formulation, 01 q , while r and c represent parameters related to the coefficient of elasticity, spacing of lightweight springs, wire density, shock absorbers, bracing, and similar factors. Delay differential equations have been widely applied in fields like automatic control, biology, and finance [4][5][6][7][8][9][10][11][12]. This has increased scholarly interest in fractional delay differential equations, distinguishing them from their integer counterparts due to their characteristic traits of 'nonlocality' and 'memory'.…”

Generalized Legendre Polynomial Configuration Method for Solving Numerical Solutions of Fractional Pantograph Delay Differential Equations

“…dy t ry t cy qt dt =+ (1.3) In this formulation, 01 q , while r and c represent parameters related to the coefficient of elasticity, spacing of lightweight springs, wire density, shock absorbers, bracing, and similar factors. Delay differential equations have been widely applied in fields like automatic control, biology, and finance [4][5][6][7][8][9][10][11][12]. This has increased scholarly interest in fractional delay differential equations, distinguishing them from their integer counterparts due to their characteristic traits of 'nonlocality' and 'memory'.…”

Generalized Legendre Polynomial Configuration Method for Solving Numerical Solutions of Fractional Pantograph Delay Differential Equations

Learn from one and predict all: single trajectory learning for time delay systems