SOME APPLICATIONS OF INTEGRATION 377H
Now try the following exercise.
Exercise 149 Further problems on mean
and r.m.s. values- The vertical heighthkm of a missile varies
with the horizontal distance dkm, and is
given byh= 4 d−d^2. Determine the mean
height of the missile fromd=0tod=4 km.
[2^23 km]. - The distances of pointsyfrom the mean value
of a frequency distribution are related to the
variatexby the equationy=x+1
x. Deter-
mine the standard deviation (i.e. the r.m.s.
value), correct to 4 significant figures for
values ofxfrom 1 to 2. [2.198]
3. A currenti=25 sin 100πtmA flows in an
electrical circuit. Determine, using integral
calculus, its mean and r.m.s. values each cor-
rect to 2 decimal places over the ranget= 0
tot=10 ms. [15.92 mA, 17.68 mA]
4. A wave is defined by the equation:
v=E 1 sinωt+E 3 sin 3ωt
whereE 1 ,E 3 andωare constants.
Determine the r.m.s. value ofvover the
interval 0≤t≤π
ω.
⎡⎣√
E 12 +E^23
2⎤⎦38.4 Volumes of solids of revolution
With reference to Fig. 38.6, the volume of revolution,
V, obtained by rotating areaAthrough one revolution
about thex-axis is given by:
V=∫baπy^2 dxy0 x = ax = bxy = f(x)AFigure 38.6
If a curvex=f(y) is rotated 360◦about they-axis
between the limitsy=candy=dthen the volume
generated,V, is given by:V=∫dcπx^2 dy.Problem 5. The curvey=x^2 +4 is rotated one
revolution about thex-axis between the limits
x=1 andx=4. Determine the volume of solid
of revolution produced.Revolving the shaded area shown in Fig. 38.7, 360◦
about thex-axis produces a solid of revolution
given by:Volume=∫ 41πy^2 dx=∫ 41π(x^2 +4)^2 dx=∫ 41π(x^4 + 8 x^2 +16) dx=π[
x^5
5+8 x^3
3+ 16 x] 41
=π[(204. 8 + 170. 67 +64)−(0. 2 + 2. 67 +16)]=420.6πcubic unitsFigure 38.7Problem 6. Determine the area enclosed by
the two curvesy=x^2 andy^2 = 8 x. If this area
is rotated 360◦about thex-axis determine the
volume of the solid of revolution produced.