LEO Atmospheric Drag Analysis and Lunar Orbit Circularization

1. February 19, 2009 [Andrew Damon] [Mission Ops] LEO Atmospheric Drag Analysis and Lunar Orbit Circularization 1

2. Atmospheric Drag for Circular Parking Orbits • Assume Thrust of • 110 mN • Assume CD = 1.0 • Analysis based on cross section area of: • Solar Panels ~ 8 m2 • OTV ~ 4 m2 • Total Area ~ 12 m2 Recommend: Parking Orbit of 400 km – Drag drops to less than 5% of Thrust, Within capabilities of Dnepr Launch Vehicle [Andrew Damon] [Mission Ops] 2

3. Lunar Orbit Circularization [Andrew Damon] [Mission Ops] “Step-down” of lunar orbit by thrusting near periapsis (braking) Goal of 110 km circular parking orbit EP thruster fired from -45o to 45o Modeled as impulsive maneuver to approximate benefit ΔV ≈ .38 m/s delivered near perilune with EP system Circularization time on the order of 4 years – not acceptable Solutions: - Raise parking orbit - Extend Earth outbound spiral - Use chemical system to deliver some ΔV 3

4. Backup Slides Curve fit for density based on altitude: Where h is altitude in km and ρ is in ng/m3 [Andrew Damon] [Mission Ops] Drag Calculations FD ~ Newtons ρ ~ kg/m3 CD ~ dimensionless v ~ m/s A ~ m2 **Can be incorporated as part of EOMs 4

5. [Andrew Damon] [Mission Ops] EP ΔV approximation -TOF for -45oto -45o determined - mo is known from time history - mdot assumed to be constant for EP - mf= mo - mdot(TOF) Just apply ideal rocket equation… Isp for system is known • ΔV = Isp*go*ln(mo / mf) • Because ΔV was applied symmetric to periapsisand this TOF was a small portion of the orbital period, the ΔV was considered impulsive for this “step-down” analysis 5