SUAAVE: Sensing Unmanned Autonomous Aerial VEhicles
Lead Research Organisation:
University of Ulster
Department Name: Sch of Computing & Information Eng
Abstract
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Organisations
- University of Ulster (Lead Research Organisation)
- Home Office Sci Dev't Branch (Project Partner)
- BT Research (Project Partner)
- Thales (United Kingdom) (Project Partner)
- Boeing (United States) (Project Partner)
- Communications Research Centre Canada (Project Partner)
- BAE Systems (United Kingdom) (Project Partner)
Publications
Luo C
(2014)
A Communication Model to Decouple the Path Planning and Connectivity Optimization and Support Cooperative Sensing
in IEEE Transactions on Vehicular Technology
Luo C
(2013)
UAV Position Estimation and Collision Avoidance Using the Extended Kalman Filter
in IEEE Transactions on Vehicular Technology
Luo C
(2015)
Hybrid Demodulate-Forward Relay Protocol for Two-Way Relay Channels
in IEEE Transactions on Wireless Communications
Patterson T
(2014)
Timely autonomous identification of UAV safe landing zones
in Image and Vision Computing
Symington A
(2010)
Probabilistic target detection by camera-equipped UAVs
Description | The SUAAVE consortium is an interdisciplinary group in the fields of computer science and engineering. The consortium's focus is to investigate and elucidate the principles underlying the control of clouds of networked resource-limited unmanned aerial vehicles (UAVs) acting as sensor platforms, that are targeted towards achieving a global objective in an efficient manner. The results of this must be communicated to a ground controller. The focus of SUAAVE lies in the creation and control of swarms of helicopter UAVs (unmanned aerial vehicles) that are individually autonomous (i.e not under the direct realtime control of a human) but that collaboratively self-organise: to sense the environment in the most efficient way possible; to respond to node failures; and to report their findings to a base station on the ground. Such clouds (or swarms or flocks) of helicopters have a wide variety of applications in both civil and military domains since they are rapidly deployable and highly survivable. In effect there are three separate capabilities for use in addressing application-specific problems: (i) ground sensing of various types; (ii) atmospheric sampling; and (iii) the ability to bridge communications, all within a rapidly deployable, survivable, hands-off package. Examples of these include: search and rescue; pollution monitoring; chemical/biological/radiological weapons plume monitoring; disaster recovery - e.g. (flood) damage assessment; sniper location; communication bridging in ad hoc situations; and overflight of sensor fields for the purposes of collecting data. The novelty of these mobile sensor systems is that their movement is controlled by fully autonomous tasking algorithms with two important objectives: first, to increase sensing coverage to rapidly identify targets; and, second, to maintain network connectivity to enable real-time communication between UAVs and ground-based crews. The project has four main scientific themes: (i) wireless networking as applied in a controllable free-space transmission environment with three free directions in which UAVs can move; (ii) control theory as applied to aerial vehicles, with the intention of creating truly autonomous agents that can be tasked but do not need a man-in-the-loop control in real time to operate and communicate; (iii) artificial intelligence and optimisation theory as applied to a real search problem; (iv) data fusion from multiple, possibly heterogeneous airborne sensors as applied to construct and present accurate information to situation commanders. |
Exploitation Route | We have been successful in taking forward two new proposals in the areas of:- 1. UAVs for Flood Monitoring as part of a DE Call managed by Imperial College London. UWS and Ulster are collaborating with Oxford and UCL and also have involvement with BT Research Labs. BT are interested in our work as it support how BT Engineers respond to key problems areas affected by floods to restore communications infrastructure 2. We are developing a proposal with FCO and Regional Police Agencies for "Very First Responders in the Presence of major Disaster Events. This falls within the EPSRC "Making Sense from Data" Call that is currently inviting Expressions of Interest. We are leveraging our work with the India-UK Advanced Technology Centre (IU-ATC) to bring forward a proposal with partners Ulster, Cambridge, UCL and Oxford. |
Sectors | Aerospace Defence and Marine Digital/Communication/Information Technologies (including Software) Education Electronics Environment Security and Diplomacy Transport Other |
URL | https://www.cs.ox.ac.uk/projects/SUAAVE/ |
Description | Our EPSRC WINES III SUAAVE Project formed part of a Strategic Review of the WINES Programme:- http://www.epsrc.ac.uk/newsevents/pubs/wired-and-wireless-intelligent-networked-systems-strategy-and-impact-workshop-report/ Due to Safety Concerns in the use and deployment of UAV Platforms we developed Standard Operating Procedures that were shared with the Home Office and also use to satisfy UK CAA. |
First Year Of Impact | 2012 |
Sector | Aerospace, Defence and Marine,Digital/Communication/Information Technologies (including Software),Electronics,Environment,Security and Diplomacy,Transport |
Impact Types | Economic Policy & public services |
Description | British Council UK-India Education Research Initiative 2005-2016 |
Amount | £51,000 (GBP) |
Organisation | British Council |
Sector | Charity/Non Profit |
Country | United Kingdom |
Start | 11/2015 |
End | 06/2016 |