A Classical Approach of Newtonian Mechanics

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8 ROTATIONAL MOTION 8.5 Centre of mass

a

̧ ̧ ̧
dx dy dz

± ±

̧

̧

̧
z dz
̧
dz

̧
dy
̧
dy

̧

̧

̧
z dz

y z
geometric centre

a x

a

h
zcm
x^
a

top view side view

Figure 74: Locating the geometric centre of a regular square-sided pyramid.

z-component of Eq. (8.20):

zcm =

̧ ̧ ̧
z dx dy dz
, (8.21)

where the integral is taken over the volume of the pyramid.

In the above integral, the limits of integration for z are z = 0 to z = h, respec-
tively (i.e., from the base to the apex of the pyramid). The corresponding limits of
integration for x and y are x, y = −a (1 − z/h)/2 to x, y = +a (1 − z/h)/2, respec-
tively (i.e., the limits are x, y = a/2 at the base of the pyramid, and x, y = 0
at the apex). Hence, Eq. (8.21) can be written more explicitly as
h
zcm = 0
0

+a (1−z/h)/2
−a (1−z/h)/2
+a (1−z/h)/2
−a (1−z/h)/2

+a (1−z/h)/2
−a (1−z/h)/2
+a (1−z/h)/2
−a (1−z/h)/2

. (8.22)


As indicated above, it makes sense to perform the x- and y- integrals before
the z-integrals, since the limits of integration for the x- and y- integrals are z-

dependent.^ Performing^ the^ x-integrals,^ we^ obtain^
h
zcm = 0
0


+a (1−z/h)/2
−a (1−z/h)/2
+a (1−z/h)/2
−a (1−z/h)/2

a (1 − z/h) dy

a (1 − z/h) dy

̧. (8.23)
dz

h

dx

dx

h
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