Flapping Wing Micro Air Vehicle Designs by SK Gupta’s Group


Students: Arvind Ananthanarayanan, Wojciech Bejgerowski, Li-Jen Chang, John Gerdes, Tobias Karch, Dominik Mueller, Guru Ramu, and Philippe Wandji
Faculty: Satyandra K. Gupta
Collaborators: Hugh Bruck and Stephen Wilkerson
Sponsors: Army MURI, ARL, NSF


MAV Name Purpose Specifications Image Video
Exploratory Bird The purpose of this design was to test the basic compliant mechanism concept and the weight distribution that leads to sustained flapping wing flight. Weight: 8.3 g  (including battery)
Wing Span: 33.1 cm
Pay Load Capability: 0 g
UMD_Explor_Bird.wmv
Small Bird This was our first effort in designing a fully steerable lightweight bird. Weight: 9.7 g (excluding battery)
Wing Span: 34.3 cm
Flapping Frequency: 12.1
Pay Load Capability: 5.7 g (including battery)
Click Here to See Video
Big Bird This was our attempt at increasing the payload of the bird to carry on-board sensors. Weight: 27.9 g (excluding battery)
Wing Span: 57.2 cm
Flapping Frequency:  4.5 Hz
Pay Load Capaility: 19.1 g (including battery)
Click Here to See Video
Big Bird with Vision We used the payload capacity of the big bird  to attach a video camera with radio transmitter to get images as seen by the bird. Weight: 42.2 g (including battery and video camera)
Wing Span: 57.2 cm
Flapping Frequency:  4.5 Hz
Click Here to See Video
Big Bird with Folding Wing By mimicking the folding of the bird’s wing, we slowed the flight velocity by 10% without any appreciable decrease in the overall weight of the bird in flight (this included weight of the bird and the payload). Weight: 29.9 g (excluding battery)
Wing Span: 57.2 cm
Flapping Frequency:  4.5 Hz
Pay Load Capability: 17.0 g (including battery)
UMD_Bird_Folding_Wings.wmv
Jumbo Bird This was our attempt at further increasing the payload of the bird to fly with an auto pilot. Weight: 38.0 g (excluding battery)
Wing Span: 63.5 cm
Flapping Frequency:  6.1 Hz
Pay Load Capability: 33.0 g (including battery)
Click Here to See Video

 


Related Publications

The following papers provide more details on our approach.

  • D. Mueller, H.A. Bruck, and S.K. Gupta. Measurement of thrust and lift forces associated with drag of compliant flapping wing for micro air vehicles using a new test stand design. Experimental Mechanics, 50(6):725–735, 2010.
  • W. Bejgerowski, J.W. Gerdes, S.K. Gupta, H.A. Bruck, and S. Wilkerson. Design and fabrication of a multi-material compliant flapping wing drive mechanism for miniature air vehicles. ASME Mechanism and Robotics Conference, Montreal, Canada, August 2010.
  • J.W. Gerdes, S.K. Gupta, H.A. Bruck, and S. Wilkerson. A review of bird-inspired flapping wing miniature air vehicle designs. ASME Mechanism and Robotics Conference, Montreal, Canada, August 2010.
  • W. Bejgerowski, A. Ananthanarayanan, D. Mueller, and S.K. Gupta.  Integrated product and process design for a flapping wing drive-mechanism. ASME Journal of Mechanical Design, 131: 061006, 2009.
  • D. Mueller, J. Gerdes, and S.K. Gupta. Incorporation of passive wing folding in flapping wing miniature air vehicles. ASME Mechanism and Robotics Conference, August 30-September 2, 2009, San Diego.

Contact

For additional information and to obtain copies of the above papers please contact:

Dr. Satyandra K. Gupta
Viterbi School of Engineering
University of Southern California
Los Angeles, California 90089-1453
Phone: 213-740-0491
Email: guptask [AT] usc [DOT] edu