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

P. Mukkavilli et al.

the ﬂier and subsequent motion of the body through air” [1]. It also deals with the

analysis of various forces generated as a result of the motion of objects through air

and the mechanism or ‘the art’ of sustaining a ﬂier, quite often heavier-than-air, ﬂying

object, or a machine aﬂoat and making it move forward. These aerodynamic forces

are inﬂuenced to a great extent by the aero-thermodynamic conditions of the air viz.,

the ambient pressure and temperature which control the density of the surrounding

air, ﬂight Mach number and the presence of aerosol. In this context, the geodetic

location or the altitude of the ﬂying object above the ground or water surface plays a

key role. The viscous nature of air also affects the ﬂight of the object depending on

whether the velocity of the ﬂier results in laminar, transition or turbulent boundary

layers on the critical surfaces controlling the ﬂight. The ﬂight is also affected by

the Reynolds number which can be deﬁned as the ratio of inertial forces to viscous

forces. This may be the case for all ﬂying objects. Likewise, the Mach Number (M),

a ratio of ﬂight velocity to the local speed of sound, affects high-speed ﬂight. If M

is less than 0.3, the ﬂight is in an incompressible regime as is mostly the case with

Micro Aerial Vehicles (MAVs) and the biological ﬂiers. This is not generally true for

an aircraft due to its larger speed and high altitude ﬂight. The biological ﬂier or the

aircraft in these cases is supported by its wings and literally ﬂoats in the air. This is

true for the insects with low mass as well. The different forces predominant in this

kind of ﬂight are aerodynamic forces comprising of vertical lift, forward thrust and

drag in addition to the weight due to the downward gravitational pull on the ﬂier.

The lift forces help in overcoming the downward gravitational pull and help the ﬂier

to take off from the ground or rise to different heights. Similarly, thrust is needed

for the ﬂier to propel forward and to provide any necessary forward acceleration for

increasing the speed (velocity) of ﬂight. It may be noted that the greater the forward

velocity, the greater is the thrust needed to overcome the aerodynamic drag and other

resisting forces.

The biological ﬂiers comprising of birds, bats and insects have differences in

phylogeny, structure and physiology. However, these ﬂiers are many times superior to

man-made ﬂying objects like the aeroplanes and helicopters, during their low-speed

ﬂight. The rockets and missiles operate at much higher speeds. The aeroplanes, for

example, derive their forward thrust through the propellers or the propelling jet, and

the lift is generated by the relative airﬂow over the asymmetrical or cambered, ﬁxed-

wing surfaces, which are suitably contoured. The helicopter rotor by virtue of the

blade pitch angle settings is both collective and cyclic and the blade rotation develops

the necessary lift as well as the forward thrust. A tail rotor helps in producing the

balancing counter-torque to arrest the body rotation. The alteration in the lift force in

a ﬁxed-wing aircraft is achieved by adjusting the angle of attack which controls the

relative direction of airﬂow with reference to the wing chord-line. The greater the

angle of attack, the higher is the lift developed. In the case of ﬁxed-wing aircrafts,

if the angle of attack exceeds around 16°, it is counterproductive with the resulting

stalling and separation of the airﬂow over the wing. This leads to a total loss in the

lift, increased drag and a possible loss in height of the ﬂier leading to an accident. It

may be mentioned that it is usually very difﬁcult for the aircraft to recover from the

stall and restore its normal ﬂight. It is interesting to note that in many biological ﬂiers