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http://dx.doi.org/10.7735/ksmte.2014.23.1.021

Measurement of Archer's Paradox Size using Multiple Frames  

Kim, Jonggeun (Department of Electrical and Computer Engineering)
Jeong, Yeongsang (Department of Electrical and Computer Engineering)
Song, Moonjae (ShinKwang Leports Co., Ltd.)
Kim, Sungshin (Department of Electrical Engineering)
Publication Information
Journal of the Korean Society of Manufacturing Technology Engineers / v.23, no.1, 2014 , pp. 21-26 More about this Journal
Abstract
An arrow produced by a manufacturing process is evaluated using the archer's paradox and the intensity of the impact point. The accuracy rate in particular is changed by the arrow's vibrational movement, which is called the archer's paradox. The archer's paradox occurs not only in the right, left, upward, and downward directions, but in all directions. The optimized value of the archer's paradox has not been studied yet. This paper proposes to measure the archer's paradox to determine its optimized value. Measuring the archer's paradox using a high-speed camera is expensive, and it is difficult to translate the result to a numerical value. However, the device for measuring the archer's paradox proposed in this paper is inexpensive, and the results are easy to convert to a numerical value. Therefore, this device is more suitable for optimization of the archer's paradox than a high-speed camera. In this paper, we propose to measure the size of the paradox using multiple frames, which can measure the position of an arrow moving at a speed of 300km/h to within millimeters. We calculate the size of the paradox experimentally using the measured location in each frame. This value is not an approximate value, but an accurate numerical value.
Keywords
Archer's paradox; Intensity of impact point; High speed camera; Multi-frame;
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Times Cited By KSCI : 4  (Citation Analysis)
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