Beeman's algorithm: Difference between revisions

Beeman's algorithm ^[1] is is a method for numerically integrating ordinary differential equations, generally position and velocity, which is closely related to Verlet integration.

${\displaystyle x(t+\Delta t)=x(t)+v(t)\Delta t+({\frac {2}{3}}a(t)-{\frac {1}{6}}a(t-\Delta t))\Delta t^{2}+O(\Delta t^{4})}$

${\displaystyle v(t+\Delta t)=v(t)+({\frac {1}{3}}a(t+\Delta t)+{\frac {5}{6}}a(t)-{\frac {1}{6}}a(t-\Delta t))\Delta t+O(\Delta t^{3})}$

where x is the position, v is the velocity, a is the acceleration, t is time, and ${\displaystyle \Delta t}$ is the time-step.

A predictor-corrector variant is useful when the forces are velocity-dependent:

${\displaystyle x(t+\Delta t)=x(t)+v(t)\Delta t+{\frac {2}{3}}a(t)\Delta t^{2}-{\frac {1}{6}}a(t-\Delta t)\Delta t^{2}+O(\Delta t^{4}).}$

The velocities at time ${\displaystyle t=t+\Delta t}$ are then calculated from the positions.

${\displaystyle v(t+\Delta t)(predicted)=v(t)+{\frac {3}{2}}a(t)\Delta t-{\frac {1}{2}}a(t-\Delta t)\Delta t+O(\Delta t^{3})}$

The accelerations at time ${\displaystyle t=t+\Delta t}$ are then calculated from the positions and predicted velocities.

${\displaystyle v(t+\Delta t)(corrected)=v(t)+{\frac {1}{3}}a(t+\Delta t)\Delta t+{\frac {5}{6}}a(t)\Delta t-{\frac {1}{6}}a(t-\Delta t)\Delta t+O(\Delta t^{3})}$

See also

• Velocity Verlet algorithm

References

External links

• Beeman's algorithm entry on wikipedia