2021 IEEE International Conference on Robotics and Automation (ICRA) 2021
DOI: 10.1109/icra48506.2021.9561774
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Geometry-aware Compensation Scheme for Morphing Drones

Abstract: Recent studies have shown that enabling drones to change their morphology in flight can significantly increase their versatility in different tasks. In this paper, we investigate the aerodynamic effects caused by the partial overlap between the propellers and the main body of a morphing quadrotor during flight. We experimentally characterize such effects and design a morphology-aware control scheme to compensate them. We demonstrate the effectiveness of our approach by deploying the compensation scheme on a qu… Show more

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Cited by 16 publications
(5 citation statements)
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“…The individual thrust f i provided by a single rotor without morphing is given by Equation ( 13), where the thrust coefficient called c t is a positive constant. Considering the presence of a morphing case under the actuated thigh servo motors, we reformulate Equation ( 13) as [28]:…”
Section: Aerial Locomotion Controlmentioning
confidence: 99%
“…The individual thrust f i provided by a single rotor without morphing is given by Equation ( 13), where the thrust coefficient called c t is a positive constant. Considering the presence of a morphing case under the actuated thigh servo motors, we reformulate Equation ( 13) as [28]:…”
Section: Aerial Locomotion Controlmentioning
confidence: 99%
“…In [3], a vehicle that uses several servomotors to actuate a scissorlike structure that can shrink or expand the size of the vehicle is presented, and in [4], a single servomotor is used in conjunction with an origami structure to enable the arms of a quadcopter to shorten or lengthen during flight. Vehicles that use a central actuator to change the angle of their arms in an X-shape are presented in [5] and [6], and a vehicle that uses four servomotors to change each arm angle is presented in [7] and extended in [8]. In [9] and [10], a quadcopter design is presented that is capable of using one or more actuators to reposition the propellers of the vehicle to be above one another such that the horizontal dimension of the vehicle is reduced.…”
Section: A Related Workmentioning
confidence: 99%
“…is linear with respect to dE CE , ωB BE , and propeller thrust f p i . Recall that f p i can be computed by inverting the mapping given in(8), meaning that dE CE , ωB BE , and f p i are all linear functions of f Σ and τ B . Thus, we find that the torque about hinge i is also a linear function of f Σ and τ B .…”
mentioning
confidence: 99%
“…The same controller has been used to control and stabilize reconfigurable quadrotors with exendable arms in the series of references [15][16][17]. To optimize the consumed energy and in order to choice the appropriate configuration for each flight phase, a LQR has been applied to control a reconfigurable UAV for different flight scenarios [18,19]. A conventional PID controller has been exploited by Riviere et al [20], in order to stabilize a quadrotor with variable mechanical structure.…”
Section: Related Workmentioning
confidence: 99%