Forceful manipulation with micro air vehicles

Micro air vehicles are able to anchor onto a surface within their environment and tug objects with up to 40 times their mass. Micro air vehicles (MAVs) are finding use across an expanding range of applications. However, when interacting with the environment, they are limited by the maximum thrust they can produce. Here, we describe FlyCroTugs, a class of robots that adds to the mobility of MAVs the capability of forceful tugging up to 40 times their mass while adhering to a surface. This class of MAVs, which finds inspiration in the prey transportation strategy of wasps, exploits controllable adhesion or microspines to firmly adhere to the ground and then uses a winch to pull heavy objects. The combination of flight and adhesion for tugging creates a class of 100-gram multimodal MAVs that can rapidly traverse cluttered three-dimensional terrain and exert forces that affect human-scale environments. We discuss the energetics and scalability of this approach and demonstrate it for lifting a sensor into a partially collapsed building. We also demonstrate a team of two FlyCroTugs equipped with specialized end effectors for rotating a lever handle and opening a heavy door.

[1]  Stefano Stramigioli,et al.  Application of substantial and sustained force to vertical surfaces using a quadrotor , 2017, 2017 IEEE International Conference on Robotics and Automation (ICRA).

[2]  J. Marden Maximum Lift Production During Takeoff in Flying Animals , 1987 .

[3]  Hideyuki Tsukagoshi,et al.  Aerial manipulator with perching and door-opening capability , 2015, 2015 IEEE International Conference on Robotics and Automation (ICRA).

[4]  Aaron M. Harrington,et al.  Power and weight considerations in small, agile quadrotors , 2014, Defense + Security Symposium.

[5]  Mark R. Cutkosky,et al.  Let’s All Pull Together: Principles for Sharing Large Loads in Microrobot Teams , 2016, IEEE Robotics and Automation Letters.

[6]  Joseph R. Coelho,et al.  Foraging capacity of the great golden digger wasp Sphex ichneumoneus , 1999 .

[7]  M. Cutkosky,et al.  The Gecko’s Toe: Scaling Directional Adhesives for Climbing Applications , 2013, IEEE/ASME Transactions on Mechatronics.

[8]  Nicholas Roy,et al.  An analysis of wind field estimation and exploitation for quadrotor flight in the urban canopy layer , 2016, 2016 IEEE International Conference on Robotics and Automation (ICRA).

[9]  L. Frantsevich,et al.  Structure and mechanics of the tarsal chain in the hornet, Vespa crabro (Hymenoptera: Vespidae): implications on the attachment mechanism. , 2004, Arthropod structure & development.

[10]  D. L. Christensen,et al.  Microwedge Machining for the Manufacture of Directional Dry Adhesives , 2013 .

[11]  M. Evans,et al.  A comparison of adaptations to running, pushing and burrowing in some adult Coleoptera: especially Carabidae , 2009 .

[12]  Robert J. Wood,et al.  Progress on "Pico" Air Vehicles , 2011, ISRR.

[13]  Vijay Kumar,et al.  Energetics in robotic flight at small scales , 2017, Interface Focus.

[14]  Barbara Robinson,et al.  Evolution beyond the orb web: the web of the araneid spider Pasilobus sp., its structure, operation and construction , 1975 .

[15]  Matthew T. Mason,et al.  Progress in Nonprehensile Manipulation , 1999, Int. J. Robotics Res..

[16]  Joseph R. Coelho,et al.  Near-Optimal Foraging in the Pacific Cicada Killer Sphecius convallis Patton (Hymenoptera: Crabronidae) , 2012, Insects.

[17]  Justin Manzo,et al.  The DARPA Robotics Challenge [Competitions] , 2013, IEEE Robotics Autom. Mag..

[18]  James F. Roberts Enabling Collective Operation of Indoor Flying Robots , 2011 .

[19]  Matko Orsag,et al.  Towards valve turning using a dual-arm aerial manipulator , 2014, 2014 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[20]  Peter Fankhauser,et al.  ANYmal - a highly mobile and dynamic quadrupedal robot , 2016, 2016 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS).

[21]  Mark R. Cutkosky,et al.  Designing Compliant Spine Mechanisms for Climbing , 2012 .

[22]  Giuseppe Loianno,et al.  Aggressive Flight With Quadrotors for Perching on Inclined Surfaces , 2016 .

[23]  Eric Guizzo,et al.  Three Engineers, Hundreds of Robots, One Warehouse , 2008, IEEE Spectrum.

[24]  K. Zhang,et al.  SpiderMAV: Perching and stabilizing micro aerial vehicles with bio-inspired tensile anchoring systems , 2017, 2017 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS).

[25]  Joseph R. Coelho,et al.  Sexual size dimorphism and flight behavior in cicada killers, Sphecius speciosus , 1997 .

[26]  James H Marden,et al.  Scaling of maximum net force output by motors used for locomotion , 2005, Journal of Experimental Biology.

[27]  David J. Cappelleri,et al.  Design of the I-BoomCopter UAV for environmental interaction , 2017, 2017 IEEE International Conference on Robotics and Automation (ICRA).

[28]  Sheldon Rubin Mechanical Immittance‐ and Transmission‐Matrix Concepts , 1967 .

[29]  Kevin M. Lynch,et al.  Stable Pushing: Mechanics, Controllability, and Planning , 1995, Int. J. Robotics Res..

[30]  Warren P. Seering,et al.  On the Drive Systems for High-Performance Machines , 1984 .

[31]  Ronald S. Fearing,et al.  Robotic vertical jumping agility via series-elastic power modulation , 2016, Science Robotics.

[32]  Mark R Cutkosky,et al.  Human climbing with efficiently scaled gecko-inspired dry adhesives , 2015, Journal of The Royal Society Interface.

[33]  Matthew Spenko,et al.  Robots on the Move: Versatility and Complexity in Mobile Robot Locomotion , 2013, IEEE Robotics & Automation Magazine.

[34]  M. Evans,et al.  Locomotion in the Coleoptera Adephaga, especially Carabidae , 2009 .

[35]  Mark R. Cutkosky,et al.  A palm for a rock climbing robot based on dense arrays of micro-spines , 2016, 2016 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS).

[36]  V. Tucker The energetic cost of moving about. , 1975, American Scientist.

[37]  Mark R. Cutkosky,et al.  Three-dimensional dynamic surface grasping with dry adhesion , 2016, Int. J. Robotics Res..

[38]  Robert J. Wood,et al.  Progress on ‘pico’ air vehicles , 2012, Int. J. Robotics Res..

[39]  Kevin Blankespoor,et al.  BigDog, the Rough-Terrain Quadruped Robot , 2008 .

[40]  Robert J. Wood,et al.  Science, technology and the future of small autonomous drones , 2015, Nature.

[41]  Mark R. Cutkosky,et al.  μTugs: Enabling microrobots to deliver macro forces with controllable adhesives , 2015, 2015 IEEE International Conference on Robotics and Automation (ICRA).