Open AccessA Lean, Fast Mars Round-trip Mission Architecture: Using Current Technologies for a Human Mission in the 2030s
Author(s) -
Lora J. Bailey,
David Folta,
Brent W. Barbee,
Frank Vaughn,
B. A. Campbell,
Harley A. Thronson,
Jacob A. Englander,
Tzu Yu Lin
Publication year - 2013
Publication title -
aiaa space 2014 conference and exposition
Language(s) - English
Resource type - Conference proceedings
DOI - 10.2514/6.2013-5507
Subject(s) - mars exploration program , architecture , aerospace engineering , aeronautics , computer science , engineering , environmental science , systems engineering , astrobiology , physics , geography , archaeology
We present a lean fast-transfer architecture concept for a first human mission to Mars that utilizes current technologies and two pivotal parameters: an end-to-end Mars mission duration of approximately one year, and a deep space habitat of approximately 50 metric tons. These parameters were formulated by a 2012 deep space habitat study conducted at the NASA Johnson Space Center (JSC) that focused on a subset of recognized high- engineering-risk factors that may otherwise limit space travel to destinations such as Mars or near-Earth asteroid (NEA)s. With these constraints, we model and promote Mars mission opportunities in the 2030s enabled by a combination of on-orbit staging, mission element pre-positioning, and unique round-trip trajectories identified by state-of-the-art astrodynamics algorithms.
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