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Lunar Descent Trajectory

Published bySukarno Gunardi Modified over 6 years ago

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Presentation on theme: "Lunar Descent Trajectory"— Presentation transcript:

1 Lunar Descent Trajectory
February 5th, 2009 [John Aitchison] [Mission Ops]

2 [John Aitchison] [Mission Ops]
Descent Trajectory Goal Determine trajectory, attitude, burn time, range & altitude EOM Derivation Assumptions Moon/spacecraft system, spherical & does not rotate, point masses 2-D problem T/m varies only with changing propellant mass (no throttling) [John Aitchison] [Mission Ops]

3 [John Aitchison] [Mission Ops]
Useful Numbers Variability with: Vehicle Mass Thrust Capability Lunar Parking Orbit Time (s) Action Downrange (km) Altitude (km) 0.0 Retro 15 170.3 27° 170.1 5.7 207.5 Vertical 175.4 0.9 222.1 Touchdown [John Aitchison] [Mission Ops]

4 [John Aitchison] [Mission Ops]
Code (pg. 1) [John Aitchison] [Mission Ops]

5 [John Aitchison] [Mission Ops]
Code (pg. 2) [John Aitchison] [Mission Ops]

6 [John Aitchison] [Mission Ops]
Code (pg. 3) [John Aitchison] [Mission Ops]

7 [John Aitchison] [Mission Ops]
Code (pg. 4) [John Aitchison] [Mission Ops]

8 [John Aitchison] [Mission Ops]
Coordinate System [John Aitchison] [Mission Ops]

9 Coordinate System Definitions
[John Aitchison] [Mission Ops]

10 [John Aitchison] [Mission Ops]
Assumptions [John Aitchison] [Mission Ops]

11 [John Aitchison] [Mission Ops]
Calculations (pg. 1) [John Aitchison] [Mission Ops]

12 [John Aitchison] [Mission Ops]
Calculations (pg. 2) [John Aitchison] [Mission Ops]

13 [John Aitchison] [Mission Ops]
Calculations (pg. 3) [John Aitchison] [Mission Ops]

14 [John Aitchison] [Mission Ops]
Calculations (pg. 4) [John Aitchison] [Mission Ops]

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