Fast round-trip Mars trajectories
Abstract
This paper is concerned with the effect of limiting the overall duration or else the one-way flight time of a round trip to Mars, as reflected in the sum of impulsive velocity increments required of the spacecraft propulsion system. Ignition-to-burnout mass ratios for a hypothetical single stage spacecraft, obtained from the rocket equation by combining these delta-V sums with appropriate values of specific impulse, are used to evaluate the relative effectiveness of four high-thrust propulsion alternatives. If the flight crew goes to the surface of Mars and stays there for the duration of their stopover, it is much cheaper (in terms of delta-V) to minimize their zero-g exposure by limiting the interplanetary transit time of a conjunction-class mission (round trip time = 800-1000 days, Mars stopover = 450-700 days) than to impose the same limit on an opposition-class mission (round trip time less than 600 days, stopover = 40 days). Using solid-core nuclear thermal propulsion to fly a conjunction-class mission, for a moderate mass penalty the interplanetary transit time (each way) probably could be limited to something in the range of 4 to 6 months, depending on the launch year.
- Publication:
-
Astrodynamics 1989
- Pub Date:
- 1990
- Bibcode:
- 1990asdy.conf..506W
- Keywords:
-
- Earth-Mars Trajectories;
- Manned Mars Missions;
- Return To Earth Space Flight;
- Trajectory Optimization;
- Mission Planning;
- Nuclear Propulsion;
- Trajectory Analysis;
- Astrodynamics