A Comparison of Explicit Runge–kutta Methods

Walters, Stephen J.; Turner, Ross J.; Forbes, Lawrence K.

doi:10.1017/s1446181122000141

ANZIAM J.

2022

DOI: 10.1017/s1446181122000141

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A Comparison of Explicit Runge–kutta Methods

Stephen J. Walters

Ross J. Turner²,

Lawrence K. Forbes³

Abstract: Recent higher-order explicit Runge–Kutta methods are compared with the classic fourth-order (RK4) method in long-term integration of both energy-conserving and lossy systems. By comparing quantity of function evaluations against accuracy for systems with and without known solutions, optimal methods are proposed. For a conservative system, we consider positional accuracy for Newtonian systems of two or three bodies and total angular momentum for a simplified Solar System model, over moderate astronomical timesc… Show more

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2024

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References 33 publications

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Numerical Solution Analysis of Planetary Motion Models Using the Runge-Kutta Method

Sulthon,

Tu’sadiyah,

Bulayi

et al. 2024

Intv. Ind. J. of. Math. Ed

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Purpose of the study: This study aims to solve the planetary motion model numerically using the fourth-order Runge-Kutta method and analyze the planetary motion profile through the resulting numerical solutions. Methodology: The process is carried out by solving the planetary motion model numerically using the fourth-order Runge-Kutta method, creating a program from the numerical solution, and simulating the program with variations in the parameters of the stability of the trajectory and the distance of the planet to the sun. The simulation results are in the form of estimates of the speed of the planet's motion in the x and y directions against time, and the influence of these parameters on the trajectory and velocity graphs are analyzed. Main Findings: Simulations show that the trajectory stability parameter and the planet's distance to the sun affect the planet's trajectory and velocity graphs. On the trajectory graph, the planet's distance to the sun affects the aphelion, minor axis, and major axis values of the orbit. The closer the planet is to the sun, the smaller its orbit, and vice versa. Novelty/Originality of this study: The novelty of this research lies in the application of the fourth-order Runge-Kutta method to solve the planetary motion model numerically, without requiring function derivatives. This research also connects the numerical results with Newton's law of gravity to understand the relationship between the distance of a planet to the sun and its orbital pattern.

show abstract

Numerical Solution Analysis of Planetary Motion Models Using the Runge-Kutta Method

Sulthon,

Tu’sadiyah,

Bulayi

et al. 2024

Intv. Ind. J. of. Math. Ed

View full text Add to dashboard Cite

show abstract

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A Comparison of Explicit Runge–kutta Methods

Cited by 1 publication

References 33 publications

Numerical Solution Analysis of Planetary Motion Models Using the Runge-Kutta Method

Numerical Solution Analysis of Planetary Motion Models Using the Runge-Kutta Method

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