Physical limit of prediction for chaotic motion of three-body problem
From MaRDI portal
Publication:2299675
DOI10.1016/j.cnsns.2013.07.008zbMath1473.70019arXiv1304.2089OpenAlexW2087749597MaRDI QIDQ2299675
Publication date: 24 February 2020
Published in: Communications in Nonlinear Science and Numerical Simulation (Search for Journal in Brave)
Full work available at URL: https://arxiv.org/abs/1304.2089
Three-body problems (70F07) Approximate trajectories (pseudotrajectories, shadowing, etc.) in smooth dynamics (37C50)
Related Items
Influence of numerical noises on computer-generated simulation of spatio-temporal chaos ⋮ Extreme gravitational interactions in the problem of three black holes in general relativity ⋮ On the risks of using double precision in numerical simulations of spatio-temporal chaos ⋮ An Accurate Numerical Method and Algorithm for Constructing Solutions of Chaotic Systems ⋮ A kind of Lagrangian chaotic property of the Arnold–Beltrami–Childress flow ⋮ Clean numerical simulation: a new strategy to obtain reliable solutions of chaotic dynamic systems ⋮ Ultra-Chaos: An Insurmountable Objective Obstacle of Reproducibility and Replication ⋮ On the analysis of pseudo-orbits of continuous chaotic nonlinear systems simulated using discretization schemes in a digital computer ⋮ A Self-Adaptive Algorithm of the Clean Numerical Simulation (CNS) for Chaos ⋮ Triple collision orbits in the free-fall three-body system without binary collisions ⋮ Time-delay feedback control of a cantilever beam with concentrated mass based on the homotopy analysis method
Cites Work
- Unnamed Item
- Unnamed Item
- Unnamed Item
- Unnamed Item
- Computational uncertainty and the application of a high-performance multiple precision scheme to obtaining the correct reference solution of Lorenz equations
- VSVO formulation of the Taylor method for the numerical solution of ODEs
- Computational uncertainty principle in nonlinear ordinary differential equations. I. Numerical results
- Computational uncertainty principle in ordinary differential equations. II. Theoretical analysis
- Computational chaos - a prelude to computational instability
- Physical limits of inference
- Evolution induced catastrophe in a nonlinear dynamical model of material failure
- Collapsing of chaos in one dimensional maps
- Chaotic Evolution of the Solar System
- Solving Ordinary Differential Equations Using Taylor Series
- String Theory
- Deterministic Nonperiodic Flow
