The design of a navigation, guidance, and control system for an unmanned surface vehicle for environmental monitoring

The design of a navigation, guidance, and control system for an unmanned surface vehicle for environmental monitoring

Maintaining the ecosystem is one of the main concerns in this modern age. With the fear of ever-increasing global warming, the UK is one of the key players to participate actively in taking measures to slow down at least its phenomenal rate. As an ingredient to this process, the Springer vehicle has...

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Veröffentlicht in:Proceedings of the Institution of Mechanical Engineers. Part M, Journal of engineering for the maritime environment Journal of engineering for the maritime environment, 2008-06, Vol.222 (2), p.67-79
Hauptverfasser: Naeem, W, Xu, T, Sutton, R, Tiano, A
Format: Artikel
Sprache:eng
Schlagworte:
Climate change
Control
Control systems
Control systems design
Controllers
Data integration
Environmental monitoring
Fault tolerance
Global warming
Linear quadratic Gaussian control
Monitoring
Multisensor fusion
Navigation
Navigation systems
Normal distribution
Pollutants
Speed control
Studies
Surface craft
Surface vehicles
Tracking control systems
Unmanned aerial vehicles
Unmanned vehicles
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Zusammenfassung:Maintaining the ecosystem is one of the main concerns in this modern age. With the fear of ever-increasing global warming, the UK is one of the key players to participate actively in taking measures to slow down at least its phenomenal rate. As an ingredient to this process, the Springer vehicle has been designed and is being developed for environmental monitoring and pollutant tracking. This paper highlights the Springer hardware and software architecture including various navigational sensors, a speed controller, and an environmental monitoring unit. In addition, details regarding the modelling of the vessel are outlined which are based mainly on recent trials data. The formulation of a fault tolerant multi-sensor data fusion technique is also presented. Moreover, control strategy based on a linear quadratic Gaussian controller is developed and simulated on the Springer model.
ISSN:1475-0902
2041-3084
DOI:10.1243/14750902JEME80