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Wing/body kinematics measurement and force and moment analyses of the takeoff flight of fruitflies

  • Research Paper
  • Fluid Mechanics
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Abstract

In the paper, we present a detailed analysis of the takeoff mechanics of fruitflies which perform voluntary takeoff flights. Wing and body kinematics of the insects during takeoff were measured using high-speed video techniques. Based on the measured data, inertia force acting on the insect was computed and aerodynamic force and moment of the wings were calculated by the method of computational fluid dynamics. Subtracting the aerodynamic force and the weight from the inertia force gave the leg force. The following has been shown. In its voluntary takeoff, a fruitfly jumps during the first wingbeat and becomes airborne at the end of the first wingbeat. When it is in the air, the fly has a relatively large “initial” pitch-up rotational velocity (more than 5 000°/s) resulting from the jumping, but in about 5 wing-beats, the pitch-up rotation is stopped and the fly goes into a quasi-hovering flight. The fly mainly uses the force of jumping legs to lift itself into the air (the force from the flapping wings during the jumping is only about 5%–10% of the leg force). The main role played by the flapping wings in the takeoff is to produce a pitch-down moment to nullify the large “initial” pitch-up rotational velocity (otherwise, the fly would have kept pitching-up and quickly fallen down).

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Authors and Affiliations

  1. Ministry-of-Education Key Laboratory of Fluid Mechanics, Beihang University, 100191, Beijing, China

    Mao-Wei Chen & Mao Sun

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  1. Mao-Wei Chen
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  2. Mao Sun
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Correspondence to Mao-Wei Chen.

Additional information

The project was supported by the National Natural Science Foundation of China (11232002) and the 111 Project (B07009).

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Chen, MW., Sun, M. Wing/body kinematics measurement and force and moment analyses of the takeoff flight of fruitflies. Acta Mech Sin 30, 495–506 (2014). https://doi.org/10.1007/s10409-014-0059-0

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  • DOI: https://doi.org/10.1007/s10409-014-0059-0

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