When conventional integrators like Runge–Kutta-type algorithms are used, numerical errors can make an orbit deviate from a hypersurface determined by many constraints, which leads to unreliable numerical solutions. Scaling correction methods are a powerful tool to avoid this. We focus on their applications, and also develop a family of new velocity multiple scaling correction methods where scale factors only act on the related components of the integrated momenta. They can preserve exactly some first integrals of motion in discrete or continuous dynamical systems, so that rapid growth of roundoff or truncation errors is suppressed significantly.
When conventional integrators like Runge–Kutta-type algorithms are used, numerical errors can make an orbit deviate from a hypersurface determined by many constraints, which leads to unreliable numerical solutions. Scaling correction methods are a powerful tool to avoid this. We focus on their applications, and also develop a family of new velocity multiple scaling correction methods where scale factors only act on the related components of the integrated momenta. They can preserve exactly some first integrals of motion in discrete or continuous dynamical systems, so that rapid growth of roundoff or truncation errors is suppressed significantly.
MEI Li-Jie,WU Xin**,LIU Fu-Yao. A New Class of Scaling Correction Methods[J]. 中国物理快报, 2012, 29(5): 50201-050201.
MEI Li-Jie,WU Xin**,LIU Fu-Yao. A New Class of Scaling Correction Methods. Chin. Phys. Lett., 2012, 29(5): 50201-050201.
2012, Vol. 29 
