Abstract
This chapter describes experimental approaches exploring free-flight control in insects at various levels, in view of the biomimetic design principles they may offer for MAVs. Low-level flight control is addressed with recent studies of the aerodynamics of free-flight control in the fruit fly. The ability to measure instantaneous kinematics and aerodynamic forces in free-flying insects provides a basis for the design of flapping airfoil MAVs. Intermediate-level flight control is addressed by presenting a behavioral system identification approach. In this work, the motion processing and speed control pathways of the fruit fly were reverse engineered based on transient visual flight speed responses, providing a quantitative control model suited for biomimetic implementation. Finally, high-level flight control is addressed with the analysis of landmark-based goal navigation, for which bees combine and adapt basic visuomotor reflexes in a context-dependent way. Adaptive control strategies are also likely suited for MAVs that need to perform in complex and unpredictable environments. The integrative analysis of flight control mechanisms in free-flying insects promises to move beyond isolated emulations of biological subsystems toward a generalized and rigorous approach.
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Acknowledgments
I wish to thank to reviewers for useful comments, Chauncey Grätzel for advice on the writing, Jan Bartussek, Vasco Medici and Nicola Rohrseitz for useful comments and discussions. The work described in this chapter was funded by the following institutions: Human Frontiers Science Program (HFSP), Swiss Federal Institute of Technology (ETH) Zurich; Swiss National Science Foundation (SNSF), University of Zurich and Volkswagen Foundation.
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Fry, S.N. (2009). Experimental Approaches Toward a Functional Understanding of Insect Flight Control. In: Floreano, D., Zufferey, JC., Srinivasan, M., Ellington, C. (eds) Flying Insects and Robots. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-540-89393-6_1
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