Every
physical system has associated with it a certain point whose motion characterises the motion of the whole
system. When the system moves under some external forces, then the point moves
as if the entire mass of the system is concentrated at this point and also the external
force is applied at this point for translation motion. This point is
called the center of mass of the system. Position
of Centre of Mass
(a)
System of two particles
Consider
first a system of two particles m₁ and m₂ at distances x₁ and x₂ respectively, from some origin O. We define a
point C, the centre of mass of the system, as a distance xcm from the origin O, where xcm is defined by
xcm = (m₁ x₁ + m₂ x₂)/ m₁ + m₂
xcm can be regarded as mass -weighted mean of x₁ and x₂.
(b)
System of many particles
If the particles are distributed
in space,
xcm
= (∑ mᵢ xᵢ)/ M, ycm = (∑ mᵢ yᵢ)/ M, zcm = (∑ mᵢ zᵢ)/
M.
So,
position vector of C is given by
Example:
Find
the centre of mass of the four
point masses as shown in figure.
Solution: The total mass M = 12 kg from equation, we have
xcm = [(2kg) (3m) + (4kg) (3m) + (5kg) (-
4m) + (1kg) (- 3m)]/ 12kg = -5/12 m
ycm = [(2kg) (- 1m) + (4kg) (3m) + (5kg) (4m)
+ (1kg) (- 2m)]/ 12kg = 28/12 m
The position
of the cm is 
(c)
Centre of Mass of Continuous bodies:
For
calculating center of mass of a continuous body, we first divide the body
into suitably chosen infinitesimal
elements. The choice is usually determined by the symmetry of body.
Consider
element dm of the body having position vector
the quantity 
in equation of CM is replaced
by
dm and the discrete sum over particles ∑ m₁r₁/ M, becomes
integral over the body:
the quantity in equation of CM is replaced
bydm and the discrete sum over particles ∑ m₁r₁/ M, becomes
integral over the body: 
In
component form this equation can be
written as
XCM = 1/M ∫ xdm; YCM
= 1/M ∫ ydm and ZCM = 1/M ∫ zdm
To
evaluate the integral we must express the variable m in terms of spatial
coordinates x, y, z or.
.
Example:
The density of a thin rod of length
l varies with the distance x from one end as ρ = ρ0
x2/l2. Find the position of centre of mass of rod.
Solution:
Xcm = [∫lₒ (dm) x / ∫lₒ (dm)] = [∫lₒ
(s. dx) (ρ0
x2/l2) x / ∫lₒ (s. dx) (ρ0
x2/l2)]
Here,
s = area of cross section of rod.
Therefore, Xcm = 3l/4
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