SOME APPLICATIONS OF INTEGRATION 379H
where it balances perfectly, i.e. the lamina’scen-
tre of mass. When dealing with an area (i.e. a
lamina of negligible thickness and mass) the term
centre of areaorcentroidis used for the point
where the centre of gravity of a lamina of that shape
would lie.
Ifxandydenote the co-ordinates of the centroid
Cof areaAof Fig. 38.9, then:
x=∫baxydx
∫baydxand y=1
2∫bay^2 dx
∫baydx0 x^ =^ ax^ =^ bxyx
yCArea Ay = f(x)Figure 38.9
Problem 7. Find the position of the centroid
of the area bounded by the curvey= 3 x^2 , the
x-axis and the ordinatesx=0 andx=2.If (x,y) are co-ordinates of the centroid of the given
area then:
x=∫ 20xydx
∫ 20ydx=∫ 20x(3x^2 )dx
∫ 203 x^2 dx=∫ 203 x^3 dx
∫ 203 x^2 dx=[
3 x^4
4] 20
[x^3 ]^20=12
8=1.5y=1
2∫ 20y^2 dx
∫ 20ydx=1
2∫ 20(3x^2 )^2 dx8=1
2∫ 209 x^4 dx8=9
2[
x^5
5] 20
8=9
2(
32
5)8=18
5=3.6Hence the centroid lies at (1.5, 3.6)Problem 8. Determine the co-ordinates of
the centroid of the area lying between the curve
y= 5 x−x^2 and thex-axis.y= 5 x−x^2 =x(5−x). Wheny=0,x=0orx=5.
Hence the curve cuts thex-axis at 0 and 5 as shown
in Fig. 38.10. Let the co-ordinates of the centroid be
(x,y) then, by integration,x=∫ 50xydx
∫ 50ydx=∫ 50x(5x−x^2 )dx
∫ 50(5x−x^2 )dx=∫ 50(5x^2 −x^3 )dx
∫ 50(5x−x^2 )dx=[
5 x^3
3 −x^4
4] 50
[
5 x^2
2 −x^3
3] 50Figure 38.10