Feasibility study of a constrained Dijkstra approach for optimal path planning of an unmanned surface vehicle in a dynamic maritime environment
Optimal path planning is an important part of mission management hierarchy in a modern unmanned surface vehicle (USV) guidance, navigation and control frame work. USVs operate in a complex dynamic marine environment comprising of moving obstacles and sea surface currents. These characterising variab...
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| Published in | 2018 IEEE International Conference on Autonomous Robot Systems and Competitions (ICARSC) pp. 117 - 122 |
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| Main Authors | , , , , |
| Format | Conference Proceeding |
| Language | English |
| Published |
IEEE
01.04.2018
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| Subjects | |
| Online Access | Get full text |
| DOI | 10.1109/ICARSC.2018.8374170 |
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| Abstract | Optimal path planning is an important part of mission management hierarchy in a modern unmanned surface vehicle (USV) guidance, navigation and control frame work. USVs operate in a complex dynamic marine environment comprising of moving obstacles and sea surface currents. These characterising variables of configuration space change spatially as well as temporally. The current work investigates a well-known search technique, the Dijkstra algorithm, to resolve the problem of motion planning for a USV moving in a maritime environment. The current study extends the implementation of Dijkstra algorithm in a space cluttered with static and moving obstacles. In addition, downstream and upstream effects of sea surface currents of different intensities on optimal path planning are studied. The performance is verified in simulations with total path length and elapsed computational time considered as parameters to determine the effectiveness of the adopted approach. The results showed that the approach is effective for global path planning of USVs. |
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| AbstractList | Optimal path planning is an important part of mission management hierarchy in a modern unmanned surface vehicle (USV) guidance, navigation and control frame work. USVs operate in a complex dynamic marine environment comprising of moving obstacles and sea surface currents. These characterising variables of configuration space change spatially as well as temporally. The current work investigates a well-known search technique, the Dijkstra algorithm, to resolve the problem of motion planning for a USV moving in a maritime environment. The current study extends the implementation of Dijkstra algorithm in a space cluttered with static and moving obstacles. In addition, downstream and upstream effects of sea surface currents of different intensities on optimal path planning are studied. The performance is verified in simulations with total path length and elapsed computational time considered as parameters to determine the effectiveness of the adopted approach. The results showed that the approach is effective for global path planning of USVs. |
| Author | Singh, Yogang Sutton, Robert Sharma, Sanjay Khan, Asiya Hatton, Daniel |
| Author_xml | – sequence: 1 givenname: Yogang surname: Singh fullname: Singh, Yogang organization: Autonomous Marine Systems (AMS) Research Group, University of Plymouth, UK – sequence: 2 givenname: Sanjay surname: Sharma fullname: Sharma, Sanjay organization: Autonomous Marine Systems (AMS) Research Group, University of Plymouth, UK – sequence: 3 givenname: Robert surname: Sutton fullname: Sutton, Robert organization: Autonomous Marine Systems (AMS) Research Group, University of Plymouth, UK – sequence: 4 givenname: Daniel surname: Hatton fullname: Hatton, Daniel organization: Autonomous Marine Systems (AMS) Research Group, University of Plymouth, UK – sequence: 5 givenname: Asiya surname: Khan fullname: Khan, Asiya organization: Autonomous Marine Systems (AMS) Research Group, University of Plymouth, UK |
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| PublicationTitle | 2018 IEEE International Conference on Autonomous Robot Systems and Competitions (ICARSC) |
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| SubjectTerms | Autonomous robots Conferences Moving obstacles Ocean current Path planning Planning Safety Sea surface Uncertainty Unmanned surface vehicle |
| Title | Feasibility study of a constrained Dijkstra approach for optimal path planning of an unmanned surface vehicle in a dynamic maritime environment |
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