Relaxation RKN-type integrators that preserve two invariants for second-order (oscillatory) systems
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Publication:6653551
DOI10.1016/j.cam.2024.116300MaRDI QIDQ6653551
Publication date: 16 December 2024
Published in: Journal of Computational and Applied Mathematics (Search for Journal in Brave)
second-order systemoscillatory systemsrelaxation techniqueARKN integratorsinvariants preservationoscillation-preserving
Stability and convergence of numerical methods for ordinary differential equations (65L20) Numerical methods for initial value problems involving ordinary differential equations (65L05)
Cites Work
- Unnamed Item
- Line integral methods which preserve all invariants of conservative problems
- Linear energy-preserving integrators for Poisson systems
- Multidimensional adapted Runge-Kutta-Nyström methods for oscillatory systems
- Order conditions for ARKN methods solving oscillatory systems
- An explicit finite-difference scheme with exact conservation properties
- Composite integrators for bi-Hamiltonian systems
- Accuracy and conservation properties in numerical integration: The case of the Korteweg-de Vries equation
- Finite volume methods for multi-symplectic PDEs
- Linear, first and second-order, unconditionally energy stable numerical schemes for the phase field model of homopolymer blends
- The scalar auxiliary variable (SAV) approach for gradient flows
- A Gautschi-type method for oscillatory second-order differential equations
- General relaxation methods for initial-value problems with application to multistep schemes
- Conserved quantities of some Hamiltonian wave equations after full discretization
- Analysis of Hamiltonian boundary value methods (HBVMs): A class of energy-preserving Runge-Kutta methods for the numerical solution of polynomial Hamiltonian systems
- Numerical integration of ordinary differential equations based on trigonometric polynomials
- Linearly implicit and high-order energy-preserving relaxation schemes for highly oscillatory Hamiltonian systems
- Structure-Preserving Algorithms for Oscillatory Differential Equations II
- Hamiltonian Boundary Value Methods (Energy Conserving Discrete Line Integral Methods)
- Energy-preserving numerical schemes of high accuracy for one-dimensional Hamiltonian systems
- A General Framework for Deriving Integral Preserving Numerical Methods for PDEs
- On the Preservation of Invariants by Explicit Runge--Kutta Methods
- Geometric integration using discrete gradients
- Numerical solution of isospectral flows
- Discrete gradient methods for solving ODEs numerically while preserving a first integral
- Geometric numerical integration illustrated by the Störmer–Verlet method
- Long-Time Energy Conservation of Numerical Methods for Oscillatory Differential Equations
- Multiple Scalar Auxiliary Variable (MSAV) Approach and its Application to the Phase-Field Vesicle Membrane Model
- Structure-Preserving Algorithms for Oscillatory Differential Equations
- Implicit-explicit relaxation Runge-Kutta methods: construction, analysis and applications to PDEs
- Relaxation Runge--Kutta Methods: Conservation and Stability for Inner-Product Norms
- Relaxation Runge--Kutta Methods: Fully Discrete Explicit Entropy-Stable Schemes for the Compressible Euler and Navier--Stokes Equations
- Numerical approximations for a three-component Cahn–Hilliard phase-field model based on the invariant energy quadratization method
- A new class of energy-preserving numerical integration methods
- Geometric Numerical Integration
- A Characterization of Energy-Preserving Methods and the Construction of Parallel Integrators for Hamiltonian Systems
- Hamiltonian BVMs (HBVMs): A Family of “Drift Free” Methods for Integrating polynomial Hamiltonian problems
- Solving ODEs numerically while preserving a first integral
- Relaxation Exponential Rosenbrock-Type Methods for Oscillatory Hamiltonian Systems
- Multiple-relaxation Runge Kutta methods for conservative dynamical systems
- Note on derivation of order conditions for ARKN methods for perturbed oscillators
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