A comparison of multiple techniques for the reconstruction of entry, descent, and landing trajectories and atmospheres

Wells, Grant

05 April 2011

The primary importance of trajectory reconstruction is to assess the accuracy of pre-flight predictions of the entry trajectory. While numerous entry systems have flown, often these systems are not adequately instrumented or the flight team not adequately funded to perform the statistical engineering reconstruction required to quantify performance and feed-forward lessons learned into future missions. As such, entry system performance and reliability levels remain unsubstantiated and improvement in aerothermodynamic and flight dynamics modeling remains data poor. The comparison is done in an effort to quantitatively and qualitatively compare Kalman filtering methods of reconstructing trajectories and atmospheric conditions from entry systems flight data. The first Kalman filter used is the extended Kalman filter. Extended Kalman filtering has been used extensively in trajectory reconstruction both for orbiting spacecraft and for planetary probes. The second Kalman filter is the unscented Kalman filter. Additionally, a technique for using collocation to reconstruct trajectories is formulated, and collocation's usefulness for trajectory simulation is demonstrated for entry, descent, and landing trajectories using a method developed here to deterministically find the state variables of the trajectory without nonlinear programming. Such an approach could allow one to utilize the same collocation trajectory design tools for the subsequent reconstruction.

Implicit

Explicit

Integration

Kalman

Unscented

Extended

Huygens

Galileo

Phoenix

MER

Pathfinder

Viking

Mars 6

Vega

Venus

Earth

Mars

Jupiter

Titan

Pioneer Venus

Venera

Control

Optimal

Reconstruction

Filter

Collocation

Trajectory

Space trajectories