6
Theories on Hovering Flight of Insects
81
ϑh = M
L2
1
Bef f
K
′
(6.10)
∴ϑh = f
�
W SL, Bef f
�
(6.11)
Mechanical Oscillator Theory
Greenewalt [1] considered the oscillating wing of a biological flier as a driven
mechanical harmonic oscillator and suggested the following equation as
ϑ.ln = K (constant)
(6.12)
with a value of 3540 for the constant K and l is being the wing length in mm.
Accordingly,
ϑ.l(1 to 1.25) = 3540
(6.13)
The value of n has to be varied between 1 and 1.25 for tallying with the natural
frequency of the flier by the trial-and-error method. The value of the wing length
(l) has to be expressed in millimetres. Greenewalt confined his experiments to small
hummingbirds. This is a very cumbersome method that involves many trial-and-error
calculations by changing the power values of the index of l. Therefore, when we apply
this formula for the calculation of frequency in biological fliers, it is a long drawn
process. Hence, this theory is not generally used for calculating the insect wingbeat
frequency.
Crawford’s Theory
Crawford [2] proposed modified mass flow theory and obtained a relationship for
the wingbeat frequency of small fliers and the equation is as follows:
ϑh =
� g
4πρ
�1/2
x
�M f
Sw
(6.14)
where
M f
Mass of the flier.
Sw
Wing swept area = Stroke angle (radians) × (wing length, mm)2.
ρ
Density of air 0.001225 gm/ cm3 (for standard air at mean sea level).
g
Acceleration due to gravity = 981 cm/ s2.