Autonomous Control in Advanced Life Support Systems : Air Revitalisation within the Micro-Ecological Life Support System Alternative

Abstract: In recent years international space agencies have become more and more explicit about long term lunar and Martian space missions. With the space program Terrae Novae, the European Space Agency puts forward a focus on the development of Human & Robotic Exploration technologies essential in enabling such long term missions. An integral component of this program is the focus on Advanced Life Support Systems. Life support systems are operated to provide astronauts with life necessities like oxygen, water and food. Currently, conventional Life Support System often have a linear supply design, relying on resources shipped from Earth, with limited onboard re-usage. However, for extended space missions, this linear supply model becomes impractical due to the constraints of dry mass during space travel. Given this need, the European Space Agency initiated the MELiSSA (Micro-Ecological Life Support System Alternative) project aimed at the development of a bioregenerative life support systems. In previous works, the MELiSSA Loop has been proposed: a system design inspired by terrestial ecosystems, that consists of multiple compartments that perform specific biological functions like nitrification and biosynthesis. Due to the complex interdependence of the individual compartments and general space system requirements, the control of such this cyber-physical system forms a significant challenge. This thesis proposes a previously undescribed architecture for the MELiSSA Loop controller design that coordinates the resource distribution between the compartments and establishes atmosphere revitalisation. The architecture meets control objectives specified at high level, and at the same time satisfies the physical and operational constraints.