Biophysics of Insect Flight (N. Chari, Prasad Mukkavilli etc.)

P. Mukkavilli et al.

Modes of Insect Flight

Insect ﬂight is complicated as compared to other biological ﬂiers due to their small

mass, presence of elastic resilin at the wing joints and varieties of ﬂexible ﬂap-

ping wings adapted for high-frequency ﬂight. These types of ﬂight can broadly be

classiﬁed as follows:

(i)

Hovering Flight

(ii)

Forward Flight

(iii)

Gliding Flight

(iv)

Manoeuvring Flight

(v)

Passive Flight.

(i)

Hovering Flight: In hovering ﬂight, forward velocity is nearly zero and

the ﬂier remains in equilibrium more or less in a stationary condition. The

insect wing generates the necessary lift mainly during the downstroke and to

some extent during the upstroke. The hovering position is usefully adapted

for feeding such as nectar sucking from ﬂowers and in some cases blood

sucking from its prey. The hovering also helps in the surveillance. The wing

span remains more or less constant and the wingbeat is continuous. During

hovering, the body axis is slightly inclined with the face upward and the wing

tip movements describe a ﬁgure of ‘8’. Hovering is a costly mode of ﬂight in

terms of energy consumption. During hovering, the intake of oxygen as well as

the energy consumption increases by more than ﬁve times as compared to the

resting metabolic state. It may be noted that the hovering process results in the

creation of a set of standing vortices one above the other. This is in contrast to

the forward ﬂight. Honey bees and Bumblebees are good examples of hovering

insects during nectar sucking. Hence, the insects must draw cleaner and fresher

air from the ambient ﬂow and get rid of the vortices they have created to obtain

a periodic lift [2]. Basic aerodynamic mechanisms in hovering insects might

help in the development of insect-inspired Bio-mimicking MAVs [3–5]. The

swimming motion during hovering produces a ﬁgure of ‘8’ by the wing tips

which is an efﬁcient one.

(ii)

Forward Flight: Insect ﬂight is mainly due to a powerful downstroke and

an upward recovery stroke achieved through powerful muscular movements.

Forward ﬂight of insects comprises of upward lift and forward thrust against

gravitational force and drag. Insects have less body mass and relatively larger

wing area per unit mass as compared to Homeotherm ﬂiers (i.e. birds and bats)

and perform high wingbeat frequency ﬂight. The low wingbeat frequency in

some insects comes under the category of Neurogenic ﬂiers and it usually

ranges from 2 to 100 cps. The high wingbeat frequency in insects is known

as Myogenic and ranges from 100 to 1000 cps. The neurogenic ﬂiers are also

known as synchronous ﬂiers and the myogenic ﬂiers as asynchronous ﬂiers.

The forward velocity is usually variable from 1 to 4 m per second and is

inﬂuenced due to the small mass by the wind velocity. It is notable that when

insects ﬂy forward, their stroke plane also becomes more inclined forward