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ECAL
2007
Springer
2007
Springer
Evolution of Neural Networks for Active Control of Tethered Airfoils
Recent development in tethered airfoil i.e. kite technology allows the possibility of exploitation of wind energy at higher altitudes than achievable with traditional wind turbines, with greater efficiency and reduced costs. This study describes the use of evolutionary robotics techniques to build neurocontrollers that maximize energy recoverable from wind by kite control systems in simulation. From initially randomized starting conditions, neurocontrollers rapidly develop under evolutionary pressure to fly the kite in figure eight trajectories that have previously been shown to be an optimal path for power generation. Advantages of this approach are discussed and data is presented which demonstrates the robustness of trajectory control to environmental perturbation.
Real-time TrafficArtificial Intelligence | ECAL 2007 | Kite Control Systems | Tethered Airfoil I.e | Traditional Wind Turbines |
Related Content
| Added | 14 Aug 2010 |
| Updated | 14 Aug 2010 |
| Type | Conference |
| Year | 2007 |
| Where | ECAL |
| Authors | Allister Furey, Inman Harvey |
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