The stability of the fourth order Runge-Kutta method for the solution of systems of differential equations

Karim, Abbas I. Abdel

doi:10.1145/365170.365213

Cited by 7 publications

(2 citation statements)

References 2 publications

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“…2 on the imaginary axis, with Δz ≠ 0 [44]. The employed step size attends the RK4 stability criterion.…”

Section: Numerical Proceduresmentioning

confidence: 99%

Application of the one-dimensional drift-flux model for numerical simulation of gas–liquid isothermal flows in vertical pipes: a mechanistic approach based on the flow pattern

Lima

2020

SN Appl. Sci.

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The multiphase flow prediction becomes necessary for the technical-economical feasibility of several transportation processes in the petroleum industry, among others. Depending on the flow rates, phases' physical properties, and pipe characteristics, gas-liquid flows can assume three flow patterns: dispersed, separated, and intermittent. The drift-flux model is adopted in various commercial simulators and allows all flow patterns simulation provided that the constitutive equations are suitable for each flow pattern. The interfacial terms, the well-posedness, and the reduced number of transport equations are the main advantages of the drift-flux model in comparison with other models, such as the two-fluid model. But the constitutive laws for predicting the wall shear force are its weak point and depend on the arrangement of each flow pattern, unlike relative motion that can be determined by correlations that are flow pattern-independent or not. This work aims to perform the steady-state numerical simulation of gas-liquid flows in vertical pipes, applying a one-dimensional mechanistic approach dependent on the flow pattern, for the closing of the constitutive equations, solved in a single running algorithm. The results obtained by this approach are compared against two sets of experimental data for the pressure gradient of upward air-water vertical isothermal flow cases, presenting satisfactory results, thus demonstrating the accuracy of the approach employed.

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“…2 on the imaginary axis, with Δz ≠ 0 [44]. The employed step size attends the RK4 stability criterion.…”

Section: Numerical Proceduresmentioning

confidence: 99%

Application of the one-dimensional drift-flux model for numerical simulation of gas–liquid isothermal flows in vertical pipes: a mechanistic approach based on the flow pattern

Lima

2020

SN Appl. Sci.

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“…To compute the separation distance (equation (2)), the trajectories for both the persistence and MERCATOR models are advected using a fourth-order Runge-Kutta advection scheme (Abdel Karim, 1966). For simplicity, only the advection (i.e., the forcing of the ocean currents alone) acts on the simulated trajectories.…”

Section: Geophysical Research Lettersmentioning

confidence: 99%

The Crossover Time as an Evaluation of Ocean Models Against Persistence

Phillipson

Toumi

2018

Geophysical Research Letters

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A new ocean evaluation metric, the crossover time, is defined as the time it takes for a numerical model to equal the performance of persistence. As an example, the average crossover time calculated using the Lagrangian separation distance (the distance between simulated trajectories and observed drifters) for the global MERCATOR ocean model analysis is found to be about 6 days. Conversely, the model forecast has an average crossover time longer than 6 days, suggesting limited skill in Lagrangian predictability by the current generation of global ocean models. The crossover time of the velocity error is less than 3 days, which is similar to the average decorrelation time of the observed drifters. The crossover time is a useful measure to quantify future ocean model improvements.

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On the optimal choice of fourth-order Runge-Kutta formulas

Luther

Sierra

1970

Numer. Math.

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The stability of the fourth order Runge-Kutta method for the solution of systems of differential equations

Cited by 7 publications

References 2 publications

Application of the one-dimensional drift-flux model for numerical simulation of gas–liquid isothermal flows in vertical pipes: a mechanistic approach based on the flow pattern

Application of the one-dimensional drift-flux model for numerical simulation of gas–liquid isothermal flows in vertical pipes: a mechanistic approach based on the flow pattern

The Crossover Time as an Evaluation of Ocean Models Against Persistence

On the optimal choice of fourth-order Runge-Kutta formulas

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