Design, modelling and optimisation of morphing structures for medium altitude long endurance UAVs

Ajaj, Rafic Mohammad

January 2013

No description available.

629.1

DESIGN AND FLIGHT TESTING OF A WARPING WING FOR AUTONOMOUS FLIGHT CONTROL

Doepke, Edward Brady

01 January 2012

Inflatable-wing Unmanned Aerial Vehicles (UAVs) have the ability to be packed in a fraction of their deployed volume. This makes them ideal for many deployable UAV designs, but inflatable wings can be flexible and don’t have conventional control surfaces. This thesis will investigate the use of wing warping as a means of autonomous control for inflatable wings. Due to complexities associated with manufacturing inflatable structures a new method of rapid prototyping deformable wings is used in place of inflatables to decrease cost and design-cycle time. A UAV testbed was developed and integrated with the warping wings and flown in a series of flight tests. The warping wing flew both under manual control and autopilot stabilization.

Unmanned Aerial Vehicle

UAV

Wing Warping

Wing Morphing

Flight Testing

Aeronautical Vehicles

Other Mechanical Engineering

Structures and Materials

Modeling, control, and estimation of flexible, aerodynamic structures

Ray, Cody W.

19 April 2012

Engineers have long been inspired by nature's flyers. Such animals navigate complex environments gracefully and efficiently by using a variety of evolutionary adaptations for high-performance flight. Biologists have discovered a variety of sensory adaptations that provide flow state feedback and allow flying animals to feel their way through flight. A specialized skeletal wing structure and plethora of robust, adaptable sensory systems together allow nature's flyers to adapt to myriad flight conditions and regimes. In this work, motivated by biology and the successes of bio-inspired, engineered aerial vehicles, linear quadratic control of a flexible, morphing wing design is investigated, helping to pave the way for truly autonomous, mission-adaptive craft. The proposed control algorithm is demonstrated to morph a wing into desired positions. Furthermore, motivated specifically by the sensory adaptations organisms possess, this work transitions to an investigation of aircraft wing load identification using structural response as measured by distributed sensors. A novel, recursive estimation algorithm is utilized to recursively solve the inverse problem of load identification, providing both wing structural and aerodynamic states for use in a feedback control, mission-adaptive framework. The recursive load identification algorithm is demonstrated to provide accurate load estimate in both simulation and experiment. / Graduation date: 2012

Optimal control

load identification

morphing wings

joint extended Kalman filter

aerodynamic load estimation

Mechanical engineering

aeronautical engineering

optimal control and estimation

inverse problems

finite elements

structural dynamics

Flight control

Wing-warping (Aerodynamics)

Wings (Anatomy) -- Aerodynamics

Wings (Anatomy) -- Structural dynamics

Feedback control systems

Bioengineering