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Thursday 26 March 2015

Quantitative and Qualitative Analysis on Trend of Literature on Flapping Wing (2004 - 2014) by Bibliometric Analysis | Rezadad | International Review of Aerospace Engineering (IREASE)

Quantitative and Qualitative Analysis on Trend of Literature on Flapping Wing (2004 - 2014) by Bibliometric Analysis

Mohammad Ismaeil Rezadad, Mohammadreza Maghami








DOI: http://dx.doi.org/10.15866/irease.v7i6.4788







Abstract



Academic research on flapping wing
micro aerial vehicle (MAV) has gained popularity over the past dacade
years, and a corresponding variety of scientific sub-categories within
this field has emerged in numerous journals such as Journal of
Experimental Biology, Progress in Aerospace Sciences, and Journal of
Aircraft. This paper presents a concise literature review of flapping
wing MAV research by appraising 439 academic journal papers that are
relevant to the topic and published between 2004 and April 2014. In this
bibliometric research, these papers have been divided into different
categories and research areas, with allocations to main and
sub-categories based on primary focus for each paper. This analysis of
papers brings useful insights on the anatomy of flapping wing
literature, and assists in the creation and accumulation of knowledge in
this area. The implications discussed in this literature review should
be of keen interest for researchers and practitioners considering
flapping wing areas for future research activities. A comprehensive list
of references is also presented. It is expected that this review
provides a good resource for future research on flapping wing themes,
and will invigorate further interest in this area.
Copyright © 2014 Praise Worthy Prize - All rights reserved.

Keywords



Flapping Wing; Flapping Wing MAV; Flapping Wing Micro Aerial Vehicle; Insect Flight; Cord Flight; Bibliometric Analysis


Full Text:

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References



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T. L. Hedrick, B. Cheng, and X. Deng, "Wingbeat time and the scaling of
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N. Vandenberghe, J. Zhang, and S. Childress, "Symmetry breaking leads
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R. Madangopal, Z. A. Khan, and S. K. Agrawal, "Biologically inspired
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M. F. Platzer, K. D. Jones, J. Young, and J. S. Lai, "Flapping wing
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C. Poelma, W. Dickson, and M. Dickinson, "Time-resolved reconstruction
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J. R. Usherwood, T. L. Hedrick, C. P. McGowan, and A. A. Biewener,
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J. Whitney and R. Wood, "Aeromechanics of passive rotation in flapping
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K. Jones, C. Bradshaw, J. Papadopoulos, and M. Platzer, "Bio-inspired
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Y. Lu and G. X. Shen,
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vortices on a flapping wing," Journal of experimental biology, vol. 211,
pp. 1221-1230, 2008.
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D. B. Doman, M. W. Oppenheimer, and D. O. Sigthorsson, "Wingbeat shape
modulation for flapping-wing micro-air-vehicle control during hover,"
Journal of guidance, control, and dynamics, vol. 33, pp. 724-739.
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S.-J. Chung and M. Dorothy, "Neurobiologically inspired control of
engineered flapping flight," Journal of guidance, control, and dynamics,
vol. 33, pp. 440-453.
http://dx.doi.org/10.2514/1.45311


D. Ishihara, T. Horie, and M. Denda, "A two-dimensional computational
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in dipteran flapping flight," Journal of experimental biology, vol. 212,
pp. 1-10, 2009.
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L. N. Long and T. E. Fritz, "Object-oriented unsteady vortex lattice
method for flapping flight," Journal of Aircraft, vol. 41, pp.
1275-1290, 2004.
http://dx.doi.org/10.2514/1.7357


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Quantitative and Qualitative Analysis on Trend of Literature on Flapping Wing (2004 - 2014) by Bibliometric Analysis | Rezadad | International Review of Aerospace Engineering (IREASE)

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