SOME
APPLICATIONS OF
TRIGONOMETRY 133
9
9.1 Heights and Distances
In the previous chapter, you have studied about trigonometric ratios. In this chapter,
you will be studying about some ways in which trigonometry is used in the life around
you.
Let us consider Fig. 8.1 of prvious chapter, which is redrawn below in Fig. 9.1.
Fig. 9.1
In this figure, the line AC drawn from the eye of the student to the top of the
minar is called the line of sight. The student is looking at the top of the minar. The
angle BAC, so formed by the line of sight with the horizontal, is called the angle of
elevation of the top of the minar from the eye of the student.
Thus, the line of sight is the line drawn from the eye of an observer to the point
in the object viewed by the observer. The angle of elevation of the point viewed is
SOME APPLICATIONS OF
TRIGONOMETRY
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134 MATHEMATICS
the angle formed by the line of sight with the horizontal when the point being viewed is
above the horizontal level, i.e., the case when we raise our head to look at the object
(see Fig. 9.2).
Fig. 9.2
Now, consider the situation given in Fig. 8.2. The girl sitting on the balcony is
looking down at a flower pot placed on a stair of the temple. In this case, the line of
sight is below the horizontal level. The angle so formed by the line of sight with the
horizontal is called the angle of depression.
Thus, the angle of depression of a point on the object being viewed is the angle
formed by the line of sight with the horizontal when the point is below the horizontal
level, i.e., the case when we lower our head to look at the point being viewed
(see Fig. 9.3).
Fig. 9.3
Now, you may identify the lines of sight, and the angles so formed in Fig. 8.3.
Are they angles of elevation or angles of depression?
Let us refer to Fig. 9.1 again. If you want to find the height CD of the minar
without actually measuring it, what information do you need? You would need to know
the following:
(i) the distance DE at which the student is standing from the foot of the minar
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SOME APPLICATIONS OF TRIGONOMETRY 135
(ii) the angle of elevation, BAC, of the top of the minar
(iii) the height AE of the student.
Assuming that the above three conditions are known, how can we determine the
height of the minar?
In the figure, CD = CB + BD. Here, BD = AE, which is the height of the student.
To find BC, we will use trigonometric ratios of BAC or A.
In ABC, the side BC is the opposite side in relation to the known A. Now,
which of the trigonometric ratios can we use? Which one of them has the two values
that we have and the one we need to determine? Our search narrows down to using
either tan A or cot A, as these ratios involve AB and BC.
Therefore, tan A =
BC
AB
or cot A =
AB
,
BC
which on solving would give us BC.
By adding AE to BC, you will get the height of the minar.
Now let us explain the process, we have just discussed, by solving some problems.
Example 1 : A
tower stands vertically on the ground. From a point on the ground,
which is 15 m away from the foot of the tower, the angle of elevation of the top of the
tower is found to be 60°. Find the height of the tower.
Solution : First let us draw a simple diagram to
represent the problem (see Fig. 9.4). Here A
B
represents the tower, CB is the distance of the point
from the tower and ACB is the angle of elevation.
W
e need to determine the height of the tower, i.e.,
AB. Also, ACB is a triangle, right-angled at B.
To solve the problem, we choose the trigonometric
ratio tan 60° (or cot 60°), as the ratio involves AB
and BC.
Now, tan 60° =
AB
BC
i.e.,
3
=
AB
15
i.e., AB =
15 3
Hence, the height of the tower is
15 3
m.
Fig. 9.4
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136 MATHEMATICS
Example 2 : An electrician has to repair an
electric fault on a pole of height 5 m. She needs
to reach a point 1.3m below the top of the pole
to undertake the repair work (see Fig. 9.5). What
should be the length of the ladder that she should
use which, when inclined at an angle of 60° to
the horizontal, would enable her to reach the
required position? Also, how far from the foot
of the pole should she place the foot of the
ladder? (You may take
3
= 1.73)
Solution : In Fig. 9.5, the electrician is required to
reach the point B on the pole AD.
So, BD = AD – AB = (5 – 1.3)m = 3.7 m.
Here, BC represents the ladder
. We need to find
its length, i.e., the hypotenuse of the right triangle BDC.
Now, can you think which trigonometic ratio should we consider?
It should be sin 60°.
So,
BD
BC
= sin 60° or
3.7
BC
=
3
2
Therefore, BC =
3.7 2
3
= 4.28 m (approx.)
i.e., the length of the ladder should be 4.28 m.
Now,
DC
BD
= cot 60° =
1
3
i.e., DC =
3.7
3
= 2.14 m (approx.)
Therefore, she should place the foot of the ladder at a distance of 2.14 m from
the pole.
Fig. 9.5
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SOME APPLICATIONS OF TRIGONOMETRY 137
Example 3 : An observer 1.5 m tall is 28.5 m away
from a chimney. The angle of elevation of the top
of the chimney from her eyes is 45°. What is the
height of the chimney?
Solution : Here,
AB is the chimney, CD the
observer and ADE the angle of elevation (see
Fig. 9.6). In this case, ADE is a triangle, right
-angled
at E and we are required to find the height of the
chimney.
We have AB = AE + BE = AE + 1.5
and
DE = CB = 28.5 m
To determine AE, we choose a trigonometric ratio, which involves both AE and
DE. Let us choose the tangent of the angle of elevation.
Now, tan 45° =
AE
DE
i.e., 1 =
AE
28.5
Therefore, AE = 28.5
So the height of the chimney (AB) = (28.5 + 1.5) m = 30 m.
Example 4 : From a point P on the ground the angle of elevation of the top of a 10 m
tall building is 30°. A flag is hoisted at the top of the building and the angle of elevation
of the top of the flagstaff from P is 45°. Find the length of the flagstaff and the
distance of the building from the point P. (Y
ou may take
3
= 1.732)
Solution : In Fig. 9.7, AB denotes the height of the building, BD the flagstaff and P
the given point. Note that there are two right triangles PAB and PAD. W
e are required
to find the length of the flagstaff, i.e., DB and the distance of the building from the
point P, i.e., PA.
Fig. 9.6
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138 MATHEMATICS
Since, we know the height of the building AB, we
will first consider the right PAB.
We have tan 30° =
AB
AP
i.e.,
1
3
=
10
AP
Therefore, AP =
10 3
i.e., the distance of the building from P is
10 3
m = 17.32 m.
Next, let us suppose DB = x m. Then AD = (10 + x) m.
Now, in right PAD, tan 45° =
AD 10
AP
10 3
x
Therefore, 1 =
10
10 3
x
i.e., x = 10
31
= 7.32
So, the length of the flagstaff is 7.32 m.
Example 5 : The shadow of a tower standing
on a level ground is found to be 40 m longer
when the Sun’s altitude is 30° than when it is
60°. Find the height of the tower.
Solution : In Fig. 9.8, AB is the tower and
BC is the length of the shadow when the
Sun’s altitude is 60°, i.e., the angle of
elevation of the top of the tower from the tip
of the shadow is 60° and DB is the length of
the shadow, when the angle of elevation
is 30°.
Now, let
AB be h m and BC be x m. According to the question, DB is 40 m longer
than BC.
Fig. 9.7
Fig. 9.8
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SOME APPLICATIONS OF TRIGONOMETRY 139
So, DB = (40 + x) m
Now, we have two right triangles ABC and ABD.
In ABC, tan 60° =
AB
BC
or,
3
=
h
x
(1)
In ABD, tan 30° =
AB
BD
i.e.,
1
3
=
40
h
x
(2)
From (1), we have h =
3
x
Putting this value in (2), we get
33x
= x + 40, i.e., 3x = x + 40
i.e., x =20
So, h =
20 3
[From (1)]
Therefore, the height of the tower is
20 3
m.
Example 6 : The angles of depression of the top and the bottom of an 8 m tall building
from the top of a multi-storeyed building are 30°
and 45°, respectively. Find the height of the multi-
storeyed building and the distance between the
two buildings.
Solution : In Fig. 9.9, PC denotes the multi-
storyed building and AB denotes the 8 m tall
building. We are interested to determine the height
of the multi-storeyed building, i.e., PC and the
distance between the two buildings, i.e., AC.
Look at the figure carefully
. Observe that PB is
a transversal to the parallel lines PQ and BD.
Therefore, QPB and PBD are alternate
angles, and so are equal.
So PBD = 30°. Similarly, PAC = 45°.
In right PBD, we have
Fig. 9.9
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140 MATHEMATICS
PD
BD
= tan 30° =
1
3
or BD = PD
3
In right PAC, we have
PC
AC
= tan 45° = 1
i.e., PC = AC
Also, PC = PD + DC, therefore, PD + DC = AC.
Since, AC = BD and DC = AB = 8 m, we get PD + 8 = BD =
PD 3
(Why?)
This gives PD =
831
8
431m.
31
31 31
So, the height of the multi-storeyed building is
431 8m=43+3m
and the distance between the two buildings is also
43 3m.
Example 7 : From a point on a bridge across a river, the angles of depression of
the banks on opposite sides of the river are 30° and 45°, respectively. If the bridge
is at a height of 3 m from the banks, find the width of the river.
Solution : In Fig 9.10, A and B
represent points on the bank on
opposite sides of the river, so that
AB is the width of the river. P is a
point on the bridge at a height of 3
m, i.e., DP = 3 m.
We are
interested to determine the width
of the river, which is the length of
the side AB of the D APB.
Now, AB = AD + DB
In right APD, A = 30°.
So, tan 30° =
PD
AD
Fig. 9.10
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SOME APPLICATIONS OF TRIGONOMETRY 141
i.e.,
1
3
=
3
AD
or AD = 33 m
Also, in right PBD, B = 45°. So, BD = PD = 3 m.
Now, AB = BD + AD = 3 +
33
= 3 (1 +
3
) m.
Therefore, the width of the river is 3
31m
.
EXERCISE 9.1
1. A circus artist is climbing a 20 m long rope, which is
tightly stretched and tied from the top of a vertical
pole to the ground. Find the height of the pole, if
the angle made by the rope with the ground level is
30° (see Fig. 9.11).
2. A tree breaks due to storm and the broken part
bends so that the top of the tree touches the ground
making an angle 30° with it. The distance between
the foot of the tree to the point where the top
touches the ground is 8 m. Find the height of
the tree.
3. A contractor plans to install two slides for the children to play in a park. For the children
below the age of 5 years, she prefers to have a slide whose top is at a height of 1.5 m, and
is inclined at an angle of 30° to the ground, whereas for elder children, she wants to have
a steep slide at a height of 3m, and inclined at an angle of 60° to the ground. What
should be the length of the slide in each case?
4. The angle of elevation of the top of a tower from a point on the ground, which is 30 m
away from the foot of the tower, is 30°. Find the height of the tower.
5. A kite is flying at a height of 60 m above the ground. The string attached to the kite is
temporarily tied to a point on the ground. The inclination of the string with the ground
is 60°. Find the length of the string, assuming that there is no slack in the string.
6. A 1.5 m tall boy is standing at some distance from a 30 m tall building. The angle of
elevation from his eyes to the top of the building increases from 30° to 60° as he walks
towards the building. Find the distance he walked towards the building.
7. From a point on the ground, the angles of elevation of the bottom and the top of a
transmission tower fixed at the top of a 20 m high building are 45° and 60° respectively.
Find the height of the tower.
Fig. 9.11
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142 MATHEMATICS
8. A statue, 1.6 m tall, stands on the top of a pedestal. From a point on the ground, the
angle of elevation of the top of the statue is 60° and from the same point the angle of
elevation of the top of the pedestal is 45°. Find the height of the pedestal.
9. The angle of elevation of the top of a building from the foot of the tower is 30° and the
angle of elevation of the top of the tower from the foot of the building is 60°. If the tower
is 50 m high, find the height of the building.
10. Two poles of equal heights are standing opposite each other on either side of the road,
which is 80 m wide. From a point between them on the road, the angles of elevation of
the top of the poles are 60° and 30°, respectively. Find the height of the poles and the
distances of the point from the poles.
11. A TV tower stands vertically on a bank
of a canal. From a point on the other
bank directly opposite the tower, the
angle of elevation of the top of the
tower is 60°. From another point 20 m
away from this point on the line joing
this point to the foot of the tower, the
angle of elevation of the top of the
tower is 30° (see Fig. 9.12). Find the
height of the tower and the width of
the canal.
12. From the top of a 7 m high building, the angle of elevation of the top of a cable tower is
60° and the angle of depression of its foot is 45°. Determine the height of the tower.
13. As observed from the top of a 75 m high lighthouse from the sea-level, the angles of
depression of two ships are 30° and 45°. If one ship is exactly behind the other on the
same side of the lighthouse, find the distance between the two ships.
14. A 1.2 m tall girl spots a balloon moving
with the wind in a horizontal line at a
height of 88.2 m from the ground. The
angle of elevation of the balloon from
the eyes of the girl at any instant is
60°. After some time, the angle of
elevation reduces to 30° (see Fig. 9.13).
Find the distance travelled by the
balloon during the interval.
15. A straight highway leads to the foot of a tower. A man standing at the top of the tower
observes a car at an angle of depression of 30°, which is approaching the foot of the
Fig. 9.12
Fig. 9.13
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SOME APPLICATIONS OF TRIGONOMETRY 143
tower with a uniform speed. Six seconds later, the angle of depression of the car is found
to be 60°. Find the time taken by the car to reach the foot of the tower from this point.
9.2 Summary
In this chapter, you have studied the following points :
1. (i) The line of sight is the line drawn from the eye of an observer to the point in the
object viewed by the observer.
(ii) The angle of elevation of an object viewed, is the angle formed by the line of sight
with the horizontal when it is above the horizontal level, i.e., the case when we raise
our head to look at the object.
(iii) The angle of depression of an object viewed, is the angle formed by the line of sight
with the horizontal when it is below the horizontal level, i.e., the case when we lower
our head to look at the object.
2. The height or length of an object or the distance between two distant objects can be
determined with the help of trigonometric ratios.
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