A trigonometrically adapted 6(4) explicit Runge–Kutta–Nyström pair to solve oscillating systems

Demba, Musa Ahmed; Ramos, Higinio; Watthayu, Wiboonsak; Senu, Norazak; Ahmed, Idris

doi:10.1002/mma.8528

Cited by 5 publications

(4 citation statements)

References 25 publications

(46 reference statements)

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“…(15) is solved using three different RETOLs; as reported in Table 3, the proposed OHBM performs better than THBM and VSMM methods. Furthermore, Figure 2 shows the agreement between the exact solution and the discrete one obtained with OHBM using RETOL = 10 −10 and h 0 = 10 (16) with h 0 = 10 −1 .…”

Section: Numerical Examplementioning

confidence: 75%

“…Additional numerical techniques for solving () and related problems can be found in the literature. Examples of these methods include the harmonic balance method, spline method, energy conservation method, finite element method, boundary value method, multi‐derivative method, Trigonometric fitted method, embedded explicit method, direct integration Obrechkoff method, mesh‐free technique, Nyström method, and block method; see [13–33] for further details.…”

Section: Introductionmentioning

confidence: 99%

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A new block method with variable stepsize implementation for solving third‐order differential systems

Rufai,

Carpentieri,

Ramos

2024

Math Methods in App Sciences

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This article presents an efficient one‐step hybrid block method (OHBM) to solve third‐order initial value problems (IVPs). The proposed method is derived using interpolation and collocation techniques of the assumed exact solution and its derivatives. The theoretical properties of the OHBM are analyzed. An embedding‐like technique is utilized and executed in an adaptive mode to improve the performance of the proposed method. The OHBM's efficiency and accuracy are tested by solving practical application problems in applied sciences and engineering. The numerical solutions demonstrate that the proposed OHBM is highly efficient and provides very accurate approximations.

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Section: Numerical Examplementioning

confidence: 75%

Section: Introductionmentioning

confidence: 99%

A new block method with variable stepsize implementation for solving third‐order differential systems

Rufai,

Carpentieri,

Ramos

2024

Math Methods in App Sciences

View full text Add to dashboard Cite

show abstract

“…We tested pairs that use effectively six stages per step, namely, The six stages pair ER6(4) given in El‐Mikkawy and Rahmo 12 The six stages trigonometric fitted pair ER6(4)f given in Demba et al 13 The effectively six stages pair RKNST7(5) given in Simos and Tsitouras 14 The effectively six stages trigonometric fitted pair RKNST7(5)f presented here …”

Section: Numerical Testsmentioning

confidence: 99%

Fitted modifications of Runge–Kutta–Nyström pairs of orders 7(5) for addressing oscillatory problems

Kovalnogov

Kornilova

Khakhalev

et al. 2022

Math Methods in App Sciences

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Runge-Kutta-Nyström pair of orders 7(5) using six stages per step have been discovered very recently. Here we modify four of its weights. The resulting method integrates exactly the harmonic oscillator 𝜓 ′′ = −𝜇 2 𝜓, 𝜇 ∈ R, which serves as model problem. The new weights are O(𝜇 2 ) perturbations of the original ones. Order reduction which is usually present in such modifications is avoided.Numerical results over standard six stages pairs justify our efforts.

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“…However, it would be more efficient if numerical methods could be used to solve the problem accurately and quickly. In [4][5][6][7][8][9][10][11][12] contain such works. Multistep strategies for solving ODEs require initial values.…”

Section: Introductionmentioning

confidence: 99%

Derivation of Embedded Diagonally Implicit Methods for Directly Solving Fourth-order ODEs

Saleh,

Fawzi,

Hussain

et al. 2024

IHJPAS

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EDIRKTO, an Implicit Type Runge-Kutta Method of Diagonally Embedded pairs, is a novel approach presented in the paper that may be used to solve 4th-order ordinary differential equations of the form . There are two pairs of EDIRKTO, with three stages each: EDIRKTO4(3) and EDIRKTO5(4). The derivation techniques of the method indicate that the higher-order pair is more accurate, while the lower-order pair provides superior error estimates. Next, using these pairs as a basis, we developed variable step codes and applied them to a series of -order ODE problems. The numerical outcomes demonstrated how much more effective their approach is in reducing the quantity of function evaluations needed to resolve fourth-order ODE issues.

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A trigonometrically adapted 6(4) explicit Runge–Kutta–Nyström pair to solve oscillating systems

Cited by 5 publications

References 25 publications

A new block method with variable stepsize implementation for solving third‐order differential systems

A new block method with variable stepsize implementation for solving third‐order differential systems

Fitted modifications of Runge–Kutta–Nyström pairs of orders 7(5) for addressing oscillatory problems

Derivation of Embedded Diagonally Implicit Methods for Directly Solving Fourth-order ODEs

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