The Foldable Drone: A Morphing Quadrotor That Can Squeeze and Fly

Falanga, Davide; Kleber, Kevin; Mintchev, Stefano; Floreano, Dario; Scaramuzza, Davide

doi:10.1109/lra.2018.2885575

Cited by 228 publications

(165 citation statements)

References 28 publications

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“…Unmanned aerial robots offer many benefits for rescuers in a disaster scenario. Their overhead perspective can be useful for surveying and situational awareness (Erdelj, Natalizio, Chowdhury, & Akyildiz, ; Marconi et al, ), but they can also navigate through small spaces or fly over obstacles that may be obstructed for ground‐based platforms (Falanga, Mueggler, Faessler, & Scaramuzza, ; Falanga, Kleber, Mintchev, Floreano, & Scaramuzza, ). However, their size and power constraints often mean that their sensor payloads are restricted and their flight time is low, and their fragility requires precise perception and control to avoid collisions or collision tolerant designs, potentially limiting their effectiveness in disaster scenarios.…”

Section: State Of the Artmentioning

confidence: 99%

“…Aggressive drone flight through narrow gaps can be achieved with dynamic trajectories and active vision (left; Falanga et al, ). A target application for this approach would be to enable a flying robot to enter structures such as earthquake‐damaged buildings through small apertures in an emergency response (right; Falanga et al, ) [Color figure can be viewed at wileyonlinelibrary.com]…”

Section: State Of the Artmentioning

confidence: 99%

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The current state and future outlook of rescue robotics

Delmerico

Mintchev

Giusti

et al. 2019

Journal of Field Robotics

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241

124

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Robotic technologies, whether they are remotely operated vehicles, autonomous agents, assistive devices, or novel control interfaces, offer many promising capabilities for deployment in real-world environments. Postdisaster scenarios are a particularly relevant target for applying such technologies, due to the challenging conditions faced by rescue workers and the possibility to increase their efficacy while decreasing the risks they face. However, field-deployable technologies for rescue work have requirements for robustness, speed, versatility, and ease of use that may not be matched by the state of the art in robotics research. This paper aims to survey How to cite this article: Delmerico J, Mintchev S, Giusti A, et al. The current state and future outlook of rescue robotics.

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Section: State Of the Artmentioning

confidence: 99%

Section: State Of the Artmentioning

confidence: 99%

The current state and future outlook of rescue robotics

Delmerico

Mintchev

Giusti

et al. 2019

Journal of Field Robotics

Self Cite

241

124

View full text Add to dashboard Cite

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“…This can be simply addressed by constraining the size of the vehicle or by changing the shape of the frame on the fly. Those designs have one additional degrees of freedom (DOF) per frame arm and have been shown to either change the frame shape during flight in an adaptive morphology way (Falanga, Kleber, Mintchev, Floreano, & Scaramuzza, 2019) or by steering the motor thrust vectors in a way that the MAV can fly and hover in arbitrary orientations (Kamel et al, 2018) and therefore, pass narrow passages.…”

Section: Related Workmentioning

confidence: 99%

ARDEA—An MAV with skills for future planetary missions

Lutz

Müller

Maier

et al. 2020

Journal of Field Robotics

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We introduce a prototype flying platform for planetary exploration: autonomous robot design for extraterrestrial applications (ARDEA). Communication with unmanned missions beyond Earth orbit suffers from time delay, thus a key criterion for robotic exploration is a robot's ability to perform tasks without human intervention. For autonomous operation, all computations should be done on-board and GlobalNavigation Satellite System (GNSS) should not be relied on for navigation purposes.Given these objectives ARDEA is equipped with two pairs of wide-angle stereo cameras and an inertial measurement unit (IMU) for robust visual-inertial navigation and time-efficient, omni-directional 3D mapping. The four cameras cover a 240 ∘ vertical field of view, enabling the system to operate in confined environments such as caves formed by lava tubes. The captured images are split into several pinhole cameras, which are used for simultaneously running visual odometries. The stereo output is used for simultaneous localization and mapping, 3D map generation and collision-free motion planning. To operate the vehicle efficiently for a variety of missions, ARDEA's capabilities have been modularized into skills which can be assembled to fulfill a mission's objectives. These skills are defined generically so that they are independent of the robot configuration, making the approach suitable for different heterogeneous robotic teams. The diverse skill set also makes the micro aerial vehicle (MAV) useful for any task where autonomous exploration is needed.For example terrestrial search and rescue missions where visual navigation in GNSSdenied indoor environments is crucial, such as partially collapsed man-made structures like buildings or tunnels. We have demonstrated the robustness of our system in indoor and outdoor field tests. K E Y W O R D S aerial robotics, computer vision, exploration, GPS-denied operation, planetary robotics ---This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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“…In this effort, a custom developed MRAC flight control algorithm was implemented to accommodate for the uncertainties resulting from morphing geometry. In [ 29], the authors explore the morphing by pivoting individual arms, thus generating what they term as "H", "O" and "T" morphologies and evaluated the performance of the quadcopter in both hover conditions and while executing circular trajectories. As with most of the other approaches, a customized Linear Quadratic Regulator (LQR) controller was implemented to maintain the stability and performance of the quadcopter in its morphed configurations.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of a Baseline Controller for Autonomous “Figure-8” Flights of a Morphing Geometry Quadcopter: Flight Performance

Bai

Gururajan

2019

Drones

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This article describes the design, fabrication, and flight test evaluation of a morphing geometry quadcopter capable of changing its intersection angle in-flight. The experiments were conducted at the Aircraft Computational and Resource Aware Fault Tolerance (AirCRAFT) Lab, Parks College of Engineering, Aviation and Technology at Saint Louis University, St. Louis, MO. The flight test matrix included flights in a "Figure-8" trajectory in two different morphing configurations (21 • and 27 • ), as well as the nominal geometry configuration, two different flight velocities (1.5 m/s and 2.5 m/s), two different number of waypoints, and in three planes-horizontal, inclined, and double inclined.All the experiments were conducted using standard, off-the-shelf flight controller (Pixhawk) and autopilot firmware. Simulations of the morphed geometry indicate a reduction in pitch damping (42% for 21 • morphing and 57.3% for 27 • morphing) and roll damping (63.5% for 21 • morphing and 65% for 27 • morphing). Flight tests also demonstrated that the dynamic stability in roll and pitch dynamics were reduced, but the quadcopter was still stable under morphed geometry conditions. Morphed geometry also has an effect on the flight performance-with a higher number of waypoints (30) and higher velocity (2.5 m/s), the roll dynamics performed better as compared to the lower waypoints and lower velocity condition. The yaw dynamics remained consistent through all the flight conditions, and were not significantly affected by asymmetrical morphing of the quadcopter geometry. We also determined that higher waypoint and flight velocity conditions led to a small performance improvement in tracking the desired trajectory as well.

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The Foldable Drone: A Morphing Quadrotor That Can Squeeze and Fly

Cited by 228 publications

References 28 publications

The current state and future outlook of rescue robotics

The current state and future outlook of rescue robotics

ARDEA—An MAV with skills for future planetary missions

Evaluation of a Baseline Controller for Autonomous “Figure-8” Flights of a Morphing Geometry Quadcopter: Flight Performance

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