Development and flight performance of a biologically-inspired tailless flapping-wing micro air vehicle with wing stroke plane modulation

The tailless flapping-wing micro air vehicle (FW-MAV) is one of the most challenging problems in flapping-wing design due to its lack of tail for inherent flight stability. It must be designed in such a way that it can produce proper augmented control moments modulated by a closed-loop attitude controller for active stabilization. We propose a tailless FW-MAV with a wing stroke plane modulation mechanism, namely NUS-Roboticbird, which maneuvers by only using its flapping wings for both propulsion and attitude control. The flying vehicle has four wings comprised by two pairs, and each pair of wings and its stroke plane are driven by a motor and a servo, respectively. Attitude control moments of roll, pitch and yaw are generated by vectoring a pair of thrusts, which result from changing the flapping frequency (or motor speed) and wing stroke plane of the two pairs of wings. Free-flight tests show that the vehicle can climb and descend vertically (throttle control), fly sideways left and right (roll control), fly forwards and backwards (pitch control), rotate clockwise and counter-clockwise (yaw control), hover in mid-air (active self-stabilization), and maneuver in the figure-of-8 and fast forward/backward flight. These abilities are especially important for surveillance and autonomous flight in terms of obstacle avoidance in an indoor environment. Flight test data show that an effective mechanical control mechanism and control gains for attitude-controlled flights for roll, pitch and yaw are achieved, in particular, yaw control. Currently, the vehicle weighing 31 g and having a wingspan of 22 cm can perform fast forward flight at a speed of about 5 m s-1 (18 km h-1) and endure 3.5 min in flight with a useful payload of a 4.5 g onboard camera for surveillance.

[1]  Christophe De Wagter,et al.  A tailless aerial robotic flapper reveals that flies use torque coupling in rapid banked turns , 2018, Science.

[2]  Hoon Cheol Park,et al.  Stable vertical takeoff of an insect-mimicking flapping-wing system without guide implementing inherent pitching stability , 2012 .

[3]  S. N. Fry,et al.  The aerodynamics of hovering flight in Drosophila , 2005, Journal of Experimental Biology.

[4]  Hoon Cheol Park,et al.  Pitching Moment Generation in an Insect-Mimicking Flapping-Wing System , 2014 .

[5]  Wei Shyy,et al.  Flapping and flexible wings for biological and micro air vehicles , 1999 .

[6]  Z. Jane Wang,et al.  DISSECTING INSECT FLIGHT , 2005 .

[7]  Hoon Cheol Park,et al.  Non-Jumping Take off Performance in Beetle Flight (Rhinoceros Beetle Trypoxylus dichotomus) , 2014 .

[8]  Leif Ristroph,et al.  Stable hovering of a jellyfish-like flying machine , 2014, Journal of The Royal Society Interface.

[9]  Anders Hedenström,et al.  Aerodynamic flight performance in flap-gliding birds and bats. , 2012, Journal of theoretical biology.

[10]  Mao Sun,et al.  Insect flight dynamics: Stability and control , 2014 .

[11]  Marco Debiasi,et al.  An experimental investigation on the acoustic performance of a flapping wing Micro-Air-Vehicle , 2014 .

[12]  André Preumont,et al.  COLIBRI: A hovering flapping twin-wing robot , 2017 .

[13]  W. Shyy,et al.  Aerodynamics of Low Reynolds Number Flyers , 2007 .

[14]  Hoon Cheol Park,et al.  Flow visualization of rhinoceros beetle (Trypoxylus dichotomus) in free flight , 2012 .

[15]  C. Ellington The novel aerodynamics of insect flight: applications to micro-air vehicles. , 1999, The Journal of experimental biology.

[16]  Wu Jianghao,et al.  Aerodynamic Power Efficiency Comparison of Various Micro-Air-Vehicle Layouts in Hovering Flight , 2017 .

[17]  T Nakata,et al.  Aerodynamics of a bio-inspired flexible flapping-wing micro air vehicle , 2011, Bioinspiration & biomimetics.

[18]  Bret W Tobalske,et al.  Biomechanics of bird flight , 2007, Journal of Experimental Biology.

[19]  C. Peskin,et al.  A computational fluid dynamics of `clap and fling' in the smallest insects , 2005, Journal of Experimental Biology.

[20]  Henry Won,et al.  Development of the Nano Hummingbird: A Tailless Flapping Wing Micro Air Vehicle , 2012 .

[21]  Doyoung Byun,et al.  Flexible Wing Kinematics of a Free-Flying Beetle (Rhinoceros Beetle Trypoxylus Dichotomus) , 2012 .

[22]  C. J. Clark,et al.  Three-dimensional kinematics of hummingbird flight , 2007, Journal of Experimental Biology.

[23]  H. Park,et al.  Design and stable flight of a 21 g insect-like tailless flapping wing micro air vehicle with angular rates feedback control , 2017, Bioinspiration & biomimetics.

[24]  Jae-Hung Han,et al.  A multibody approach for 6-DOF flight dynamics and stability analysis of the hawkmoth Manduca sexta , 2014, Bioinspiration & biomimetics.

[25]  B. Tobalske,et al.  Aerodynamics of the hovering hummingbird , 2005, Nature.

[26]  Joon-Hyuk Park,et al.  Designing a Biomimetic Ornithopter Capable of Sustained and Controlled Flight , 2008 .

[27]  Myong Hwan Sohn,et al.  Flow visualization and aerodynamic load calculation of three types of clap-fling motions in a Weis-Fogh mechanism , 2007 .

[28]  Z. J. Wang,et al.  Effect of forewing and hindwing interactions on aerodynamic forces and power in hovering dragonfly flight. , 2007, Physical review letters.

[29]  Marco Debiasi,et al.  Experimental investigation of wing flexibility on force generation of a hovering flapping wing micro air vehicle with double wing clap-and-fling effects , 2017 .

[30]  Kevin Y. Ma,et al.  Controlled Flight of a Biologically Inspired, Insect-Scale Robot , 2013, Science.

[31]  M. Dickinson,et al.  Force production and flow structure of the leading edge vortex on flapping wings at high and low Reynolds numbers , 2004, Journal of Experimental Biology.

[32]  Sanjay P. Sane,et al.  Review The aerodynamics of insect flight , 2003 .

[33]  Sanjay P Sane,et al.  The aerodynamics of insect flight , 2003, Journal of Experimental Biology.

[34]  T. Weis-Fogh Unusual mechanisms for the generation of lift in flying animals. , 1975, Scientific American.

[35]  Hoon Cheol Park,et al.  Clap-and-fling mechanism in a hovering insect-like two-winged flapping-wing micro air vehicle , 2016, Royal Society Open Science.

[36]  Marco Debiasi,et al.  Pitch and Yaw Control of Tailless Flapping Wing MAVs by Implementing Wing Root Angle Deflection , 2014 .

[37]  B. Tobalske,et al.  Lift production in the hovering hummingbird , 2009, Proceedings of the Royal Society B: Biological Sciences.

[38]  Adrian L. R. Thomas,et al.  Leading-edge vortices in insect flight , 1996, Nature.

[39]  Marco Debiasi,et al.  Design, Fabrication, and Performance Test of a Hovering-Based Flapping-Wing Micro Air Vehicle Capable of Sustained and Controlled Flight , 2014 .

[40]  Hoon Cheol Park,et al.  Implementation of initial passive stability in insect-mimicking flapping-wing micro air vehicle , 2015 .

[41]  E de Margerie,et al.  Artificial evolution of the morphology and kinematics in a flapping-wing mini-UAV , 2007, Bioinspiration & biomimetics.

[42]  M. Lighthill On the Weis-Fogh mechanism of lift generation , 1973, Journal of Fluid Mechanics.

[43]  L. Bennett Clap and Fling Aerodynamics-An Experimental Evaluation , 1977 .

[44]  Marco Debiasi,et al.  Hybrid design and performance tests of a hovering insect-inspired flapping-wing micro aerial vehicle , 2016 .

[45]  Quoc Viet Nguyen,et al.  Preliminary Study on Stability of a Hovering Bi-flap Flapping Wing Platform using Cycle-Averaged Linear Models , 2016 .

[46]  G C H E de Croon,et al.  Design, aerodynamics and autonomy of the DelFly , 2012, Bioinspiration & biomimetics.

[47]  Hoon Cheol Park,et al.  Generation of Control Moments in an Insect-like Tailless Flapping-wing Micro Air Vehicle by Changing the Stroke-plane Angle , 2016 .