Predictive-Reactive Scheduling for Space Missions in Small Satellite Clusters

Task scheduling in small satellites clusters is an important optimization problem because of limited resources and various constraints. Specifically, automated and dynamic scheduling is necessary for practical schedule and real-time response of exceptions, whereas it makes the problem more complicat...

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Vydáno v:2016 International Symposium on Computer, Consumer and Control (IS3C) s. 475 - 480
Hlavní autoři: Jin Wu, Lixiang Liu, Xiaohui Hu
Médium: Konferenční příspěvek
Jazyk:angličtina
Vydáno: IEEE 01.07.2016
Témata:
Automated spacecraft
Dynamic scheduling
Greedy Algorithm
Heuristic algorithms
Link Status Forecasting
Predictive-Reactive Scheduling
Satellites
Schedules
Small Satellite Cluster
Space missions
Topology
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Shrnutí:Task scheduling in small satellites clusters is an important optimization problem because of limited resources and various constraints. Specifically, automated and dynamic scheduling is necessary for practical schedule and real-time response of exceptions, whereas it makes the problem more complicated. In this paper, a predictive-reactive scheduling model has been proposed for space missions in heterogeneous small satellite clusters, which is realized by the hybrid of periodic task scheduling and dynamic adjustment. In the model, the characteristics and constraints of various space missions are abstracted and then multi-types of tasks are defined from different perspectives. Additionally, the link status is predicted and introduced as the communication constraint in the scheduling process, due to the frequent topology changes and the unreliable communication links. A priority-based scheduling algorithm ELSFT has been proposed and applied in the scheduling process. By compared with both classis greedy algorithms and the latest heuristic search algorithm, the experimental results show that our approach provides real-time schedules with high completion rate and minimum makespan.
DOI:10.1109/IS3C.2016.125