Abstract
Insects use dynamic articulation and actuation of their abdomen and other appendages to augment aerodynamic flight control. These dynamic phenomena in flight serve many purposes, including maintaining balance, enhancing stability, and extending maneuverability. The behaviors have been observed and measured by biologists but have not been well modeled in a flight dynamics framework. Biological appendages are generally comparatively large, actuated in rotation, and serve multiple biological functions. Technological moving masses for flight control have tended to be compact, translational, internally mounted and dedicated to the task. Many flight characteristics of biological flyers far exceed any technological flyers on the same scale. Mathematical tools that support modern control techniques to explore and manage these actuator functions may unlock new opportunities to achieve agility. The compact tensor model of multibody aircraft flight dynamics developed here allows unified dynamic and aerodynamic simulation and control of bioinspired aircraft with wings and any number of idealized appendage masses. The demonstrated aircraft model was a dragonfly-like fixed-wing aircraft. The control effect of the moving abdomen was comparable to the control surfaces, with lateral abdominal motion substituting for an aerodynamic rudder to achieve coordinated turns. Vertical fuselage motion achieved the same effect as an elevator, and included potentially useful transient torque reactions both up and down. The best performance was achieved when both moving masses and control surfaces were employed in the control solution. An aircraft with fuselage actuation combined with conventional control surfaces could be managed with a modern optimal controller designed using the multibody flight dynamics model presented here.
Highlights
The potential applications of small unmanned aerial vehicles (SUAVs) for both military and civil applications continue to drive interest in their design
The results showed that moving-mass control (MMC) outperformed control surfaces, since the moving masses had no effect on the drag of the airship
The flight dynamics model of the conceptual dragonfly-inspired straight-wing aircraft (DISWA) was simulated in the MATLAB/Simulink environment [130]
Summary
The potential applications of small unmanned aerial vehicles (SUAVs) for both military and civil applications continue to drive interest in their design. Animals actively change their body posture, and mass distribution, to produce forces and moments for propulsion and control [3,4]. Relies on the ability of the animal to optimize the benefits of three main physical mechanisms to control posture: aerodynamic lift and drag on wings and body [5,6], control of the center of body mass and distance to aerodynamic force vectors [3,7], and body moments of inertia quantities and rates through active changes in body shape [8]. Moving masses generate moments due to gravity or change the inertia properties for the purpose of controlling the motion of the vehicle. Most efforts have focused on employing movement of internal masses for trim, attitude, stability margin, detumbling of spinning spacecraft, trajectory, orbit, glide path and depth control
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