- INTRODUCTION
- MEASUREMENT OF ANGLES
- TRIGONOMETRIC RATIOS
- FUNDAMENTAL IDENTITIES
- HEIGHTS AND DISTANCES
Trigonometry
Trigonometry is a branch of mathematics that deals with the measurements of the sides and the angles of triangles and the relationships between them.
An angle is the union of two rays having a common end-point, called the vertex. The magnitude of the angle is the amount of rotation that separates the two rays. Angles are measured in degrees or radians. The system of measuring angles in degrees is called the sexagesimal system and the system of measuring angles in radians is called the circular system.
DEGREES
One complete rotation around a point is
measured as 360 degrees (360
).
RADIAN
One radian is the angle subtended at the
centre of a circle by an arc of length equal to the radius of the circle. One
complete rotation around a circle is measured as 2
radians. One radian is written as 1 rad or 1c.
360
= 2
rad
The six trigonometric ratios are sine (sin), cosine (cos), tangent (tan), cosecant (cosec), secant (sec) and cotangent (cot).
TRIGONOMETRIC RATIOS OF ACUTE ANGLES
Consider a right triangle XYZ where the
lengths of sides are as shown. 
is the angle between the base and the hypotenuse.
For a given value of ,
the values of trigonometric ratios are constant, irrespective of the lengths of
sides.
The angles 0,
30
(/6
rad), 45
(/4
rad), 60(/3
rad), 90(/2
rad), 180
(
rad), 270
(3/2
rad) and 360(2)
rad are called standard angles and their trigonometric ratios are as follows.
These values should be memorised as they are quite useful in solving problems in
geometry.
|
Find the value of
Solution: 2sin2 This is a quadratic equation. Let sin
|
2x2 – 3x + 1 = 0
|
Solution:
By Pythagoras theorem, AC = 13 units.
|
|
then what is the value of [FMS 2009]
Solution: Let cot
Hence, option 3. |
TRIGONOMETRIC RATIOS OF ANGLES GREATER
THAN 90
The definitions of trigonometric ratios of
angles that are greater than 90
are out of scope of this chapter. The values of such ratios, however, can be
easily calculated using certain properties of the ratios.
As 360
0,
sin (–)
= –sin
cos (–)
= cos
tan (–)
= –tan
Trigonometric ratios of angles greater than
90
can be found using the above figure as shown in the following.
REMEMBER
- All trigonometric ratios of angles in the I quadrant are positive.
- Only sine and cosecant are positive for angles in the II quadrant.
- In the III quadrant, only tangent and cotangent are positive.
- Whereas, only cosine and secant are positive in the IV quadrant.
|
If cos [IIFT 2007] (1) (3) 1(4) None of these
Solution: Let (
= 0
Hence, option 2. |
,
,
and 
are four angles of a cyclic quadrilateral, then the value of
1(2) 0
For all values of ,
sin2
+ cos2
= 1
1 + tan2
= sec2
1 + cot2
= cosec2
|
[IIFT 2008]
Solution:
Similarly,
Hence, option 2. |
Consider an object that is at a higher level than the point from which it is observed. Then the angle that the line of sight makes with the horizontal is called the angle of elevation.
|
Amar is standing at a point C, 10 metres away from
the foot of a tower AB. The angle of elevation of the top of the tower
(point A) is 60
Solution: Assume that the height of the tower is h.
|
Consider an object that is at a lower level than the point from which it is observed. Then the angle that the line of sight makes with the horizontal is called the angle of depression.
|
Niraj stands at the point A, which is the top of a
tower AB, 20 metres in height. At a certain distance away from the foot of
the tower, at point C, stands a cat. The angle of depression of the cat
from the top of the tower is 30
Solution: Assume that the distance of the cat from the foot of the tower is d.
|
|
Jayesh is standing on top of a railway bridge
watching an approaching train. The angle of depression of the topmost
point of the start of the train as it comes into sight is 30
Solution:
From the figure, JP = 50 feet.
Also,
|
JQP
= 45
|
A car is being driven, in a straight line and at a
uniform speed, towards the base of a vertical tower. The top of the tower
is observed from the car and, in the process, it takes 10 minutes for the
angle of elevation to change from 45 [CAT 2003 Re-Test] 
Solution: Let x be the distance from the later position
of the car and the tower (i.e. when the angle of elevation was 60
Since the triangle formed (i.e. ∆ABD) is a 30°-60°-90° triangle, we have, height of the tower, h =
Now, since the triangle formed by the initial position of the car (i.e. ∆ABC) is an isosceles triangle, AB = BC i.e.BC =
Time taken to travel distance DC is 10 minutes, thus,
Time taken to travel distance x
Hence, option 1. |
x = x (
1)
|
When the sunray’s inclination increases from
30 [SNAP 2008]
(1) 50.9 m(2) 51.96 m (3) 48.8 m(4) None of these
Solution:
When the angle of inclination of the sun’s rays
When Let OA = x
AB = OB – OA = 2x = 60,
Thus, height of tower = 51.96 metres. Hence, option 2. |
30 = 51.96 metres.
|
Find the length of the shorter diagonal of a rhombus
having side 10 cm and one pair of opposite angles measuring 30
Solution:
AM
ΔAMC is a right triangle.
|
DC 
5.17 cm
|
The diagonals of rectangle ABCD intersect at the
origin O.
Solution:
Consider the figure. P is the mid point of AD.
In ΔAOB, AO = OB. As
|
|
A warship and a submarine (completely submerged in
water) are moving horizontally in a straight line. The Captain of the
warship observers that the submarine makes an angle of depression of
30 [IIFT 2009]
Question 1: Find the distance between them after 30 min from the initial point of reference.
Solution: Refer to the following figure:
The vertical distance between the warship and the submarine = 25 km
Hence, option 1.
Question 2: If both are moving in same direction and the submarine is ahead of the warship in both the situations, then the speed of the warship, if the ratio of the speed of warship to that of the submarine is 2: 1, is:
Solution: Let the speed of the submarine be x kmph. Then the speed of the warship is 2x kmph. Distance travelled by the warship in 30 minutes = x km Distance travelled by the submarine in 30 minutes = 0.5x km
From the figure,
Hence, option 4. |
