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Abstract

This article describes the results of some experiments concerning wing morphology and flight performance of some flying insects: cicadas, dragonflies, and gadflies. First, the wing structures of these insects are measured down to the minutest detail by a three-dimensional curve-shaped measuring system. The surface shapes of the insect wings are mapped by distinct three-dimensional images. From the three-dimensional images, correlation coefficients are calculated by comparisons of the distribution of undulation on the wings. The surface shapes and the correlation coefficients show a difference in functions for flapping flight between each wing. Second, the distribution of velocity fields around a flapping cicada and a flapping dragonfly are visualized with a PIV system to identify the airflow generated by the wings. The distribution of velocity vectors for one stroke of a dragonfly wing is explained in the article. Additionally, the difference of airflow around the wings of a dragonfly and a cicada are revealed. It is found that the flapping forewing of the dragonfly carries out an important motion in its highly efficient flight.

Keywords

biomechanics flapping flight of insect morphology of wing PIV system

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References

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Tsuyuki, K. and Sudo, S. 2002

“Three-dimensional Structure of a Wing and Flow Field around a Flapping Dragonfly with the PIV System (in Japanese),”

Transactions of the Japan Society of Mechanical Engineers Series B, 68: 3392-3399 .

Morphology of Insect Wings and Airflow Produced by Flapping Insects

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