This paper presents a method for simulating the flight of a passively controlled rocket in six degrees of freedom, and the descent under parachute in three degrees of freedom. Also presented is a method for modeling the uncertainty in both the rocket dynamics and the atmospheric conditions using stochastic parameters and the Monte Carlo method. Included within this, we present a method for quantifying the uncertainty in the atmospheric conditions using historical atmospheric data. The core simulation algorithm is a numerical integration of the rocket’s equations of motion using the Runge-Kutta-Fehlberg method. The position of the rocket’s center of mass is described using three dimensional Cartesian coordinates and the rocket’s orientation is described using quaternions. Input parameters to the simulator are made stochastic by adding Gaussian noise. In the case of atmospheric parameters, the variance of the noise is a function of altitude and noise at adjacent altitudes is correlated. The core simulation ...
[1]
Charles S. Peskin,et al.
2-D Parachute Simulation by the Immersed Boundary Method
,
2006,
SIAM J. Sci. Comput..
[2]
Louis D. Duncan,et al.
SIX DEGREE OF FREEDOM DIGITAL SIMULATION MODEL FOR UNGUIDED FIN-STABILIZED ROCKETS
,
1964
.
[3]
Radford M. Neal.
Pattern Recognition and Machine Learning
,
2007,
Technometrics.
[4]
William H. Press,et al.
Numerical recipes
,
1990
.
[5]
Vladimir Dobrokhodov,et al.
Six-Degree-of-Freedom Model of a Controlled Circular Parachute
,
2002
.
[6]
Rahil Baber,et al.
Rigid body simulation
,
2006
.