Spacecraft Autonomous Reaction Capabilities, Control Approaches and Self-Aware Computing
K. Schilling, J. Walter, and S. Kounev. Self-Aware Computing Systems, Springer Verlag, Berlin Heidelberg, Germany, (2017)
Abstract
Space exploration missions require very challenging autonomous reaction capabilities, as spacecraft have to react appropriately to the partially unknown environment in time critical situations, where direct human interaction is often impossible due to significant signal propagation delays related to the huge distances. In particular, interplanetary exploration missions are especially demanding; therefore the missions CASSINI-HUYGEN (landing on the Saturnian moon) and ROSETTA (the accompanying and landing on a comet) will be emphasized. Today also distributed, networked, small satellites for telecommunication and Earth observation applications promise a paradigm shift compared to the traditional multi-functional big spacecraft and could benefit from self-aware computing capabilities.
%0 Book Section
%1 ScWaKo-space
%A Schilling, Klaus
%A Walter, Jürgen
%A Kounev, Samuel
%B Self-Aware Computing Systems
%C Berlin Heidelberg, Germany
%D 2017
%E Kounev, Samuel
%E Kephart, Jeffrey O.
%E Milenkoski, Aleksandar
%E Zhu, Xiaoyun
%I Springer Verlag
%K Dagstuhl_Book_Chapter Self-adaptive-systems Self-aware-computing descartes t_bookchapter
%T Spacecraft Autonomous Reaction Capabilities, Control Approaches and Self-Aware Computing
%X Space exploration missions require very challenging autonomous reaction capabilities, as spacecraft have to react appropriately to the partially unknown environment in time critical situations, where direct human interaction is often impossible due to significant signal propagation delays related to the huge distances. In particular, interplanetary exploration missions are especially demanding; therefore the missions CASSINI-HUYGEN (landing on the Saturnian moon) and ROSETTA (the accompanying and landing on a comet) will be emphasized. Today also distributed, networked, small satellites for telecommunication and Earth observation applications promise a paradigm shift compared to the traditional multi-functional big spacecraft and could benefit from self-aware computing capabilities.
@incollection{ScWaKo-space,
abstract = {Space exploration missions require very challenging autonomous reaction capabilities, as spacecraft have to react appropriately to the partially unknown environment in time critical situations, where direct human interaction is often impossible due to significant signal propagation delays related to the huge distances. In particular, interplanetary exploration missions are especially demanding; therefore the missions CASSINI-HUYGEN (landing on the Saturnian moon) and ROSETTA (the accompanying and landing on a comet) will be emphasized. Today also distributed, networked, small satellites for telecommunication and Earth observation applications promise a paradigm shift compared to the traditional multi-functional big spacecraft and could benefit from self-aware computing capabilities.},
added-at = {2020-04-05T23:16:19.000+0200},
address = {{Berlin Heidelberg, Germany}},
author = {Schilling, Klaus and Walter, J{\"u}rgen and Kounev, Samuel},
biburl = {https://www.bibsonomy.org/bibtex/2d9431d3ef18e9879d81f3758b50bb41f/se-group},
booktitle = {{Self-Aware Computing Systems}},
editor = {Kounev, Samuel and Kephart, Jeffrey O. and Milenkoski, Aleksandar and Zhu, Xiaoyun},
interhash = {5ba861bbb86757cd6bd6f5b43da1599e},
intrahash = {d9431d3ef18e9879d81f3758b50bb41f},
keywords = {Dagstuhl_Book_Chapter Self-adaptive-systems Self-aware-computing descartes t_bookchapter},
publisher = {{Springer Verlag}},
timestamp = {2020-10-06T14:16:19.000+0200},
title = {{Spacecraft Autonomous Reaction Capabilities, Control Approaches and Self-Aware Computing}},
year = 2017
}