Lines and Angles PDF

Summary

This document is about Geometry, discussing lines and angles. The focus is on fundamental ideas like points, lines, rays, and line segments, and how these form the basis of plane geometry.

Full Transcript

2 Lines and Angles

In this chapter, we will explore some of the most basic ideas of
geometry including points, lines, rays, line segments and angles.
These ideas form the building blocks of ‘plane geometry’, and will
help us in understanding more advanced topics in geometry such as
the construction and analysis of different shapes.

2.1 Point
Mark a dot on the paper with a sharp tip of a pencil. The sharper the
tip, the thinner will be the dot. This tiny dot will give you an idea of
a point. A point determines a precise location, but it has no length,
breadth or height. Some models for a point are given below.

The tip of a The sharpened The pointed
compass end of a pencil end of a needle

If you mark three points on a piece of paper,
you may be required to distinguish these three Z P
points. For this purpose, each of the three points
may be denoted by a single capital letter such as T

Chapter 2_Lines and Angles.indd 13 13-08-2024 16:14:25
 Ganita Prakash | Grade 6

Z, P and T. These points are read as ‘Point Z’, ‘Point P’ and ‘Point T’. Of
course, the dots represent precise locations and must be imagined to be
invisibly thin.

2.2 Line Segment
A
Fold a piece of paper and unfold it. Do you
see a crease? This gives the idea of a line
segment. It has two end points, A and B.
Mark any two points A and B on a sheet of
paper. Try to connect A to B by various B
routes (Fig. 2.1).
What is the shortest route from A to B? B
This shortest path from point A to Point B
(including A and B) as shown here is called
the line segment from A to B. It is denoted by
A
either AB or BA. The points A and B are called
Fig. 2.1
the end points of the line segment AB.

2.3 Line
m
Imagine that the line segment from A to B (i.e.,
B
AB) is extended beyond A in one direction and
beyond B in the other direction without any
end (see Fig. 2.2). This is a model for a line. Do A
you think you can draw a complete picture of Fig. 2.2
a line? No. Why?
A line through two points A and B is written as AB. It extends
forever in both directions. Sometimes a line is denoted by a letter like
l or m.
Observe that any two points determine a unique line that passes
through both of them.

14

Chapter 2_Lines and Angles.indd 14 13-08-2024 16:14:25
 Lines and Angles

2.4 Ray
A ray is a portion of a line that starts at one point (called the starting
point or initial point of the ray) and goes on endlessly in a direction.
The following are some models for a ray:

Beam of light from a Ray of light from a torch Sun rays
lighthouse

Look at the diagram (Fig. 2.3) of a ray. Two points are
marked on it. One is the starting point A and the other P
is a point P on the path of the ray. We then denote the
ray by AP.
A
Fig. 2.3
Figure it Out

1.
Rihan marked a point Sheetal marked two points
on a piece of paper. on a piece of paper. How
How many lines can he many different lines can
draw that pass through she draw that pass through
the point? both of the points?

Can you help Rihan and Sheetal find their answers?

15

Chapter 2_Lines and Angles.indd 15 13-08-2024 16:14:25
 Ganita Prakash | Grade 6

2. Name the line segments in Fig. 2.4. Which of the five marked
points are on exactly one of the line segments? Which are on two
of the line segments?
Q

M
R

P

L
Fig. 2.4

3. Name the rays shown in Fig. 2.5. Is T the starting point of each of
these rays?

A

T
N B
Fig. 2.5

4. Draw a rough figure and write labels appropriately to illustrate
each of the following:

a. OP and OQ meet at O.
b. XY and PQ intersect at point M.
c. Line l contains points E and F but not point D.
d. Point P lies on AB. 

5. In Fig. 2.6, name:
a. Five points
B
b. A line
O C
c. Four rays
E
d. Five line segments D
Fig. 2.6

16

Chapter 2_Lines and Angles.indd 16 13-08-2024 16:14:25
 Lines and Angles

6. Here is a ray OA (Fig. 2.7). It starts at O and A

passes through the point A. It also passes B

through the point B.
a. Can you also name it as OB ? Why?
O
b. Can we write OA as AO ? Why or why not?
Fig. 2.7

2.5 Angle D

m
An angle is formed by two rays having a ar
common starting point. Here is an angle
B
formed by rays BD and BE where B is vertex
the common starting point (Fig. 2.8). arm
The point B is called the vertex of the
E
angle, and the rays BD and BE are called Fig. 2.8
the arms of the angle. How can we name
this angle? We can simply use the vertex and say that it is the Angle B.
To be clearer, we use a point on each of the arms together with the
vertex to name the angle. In this case, we name the angle as Angle DBE
or Angle EBD. The word angle can be replaced by the symbol ‘∠’, i.e.,
∠DBE or ∠EBD. Note that in specifying the angle, the vertex is always
written as the middle letter.
To indicate an angle, we use a small curve at the vertex (refer
to Fig. 2.9).
Vidya has just opened her book. Let us observe her opening the
cover of the book in different scenarios.

Case 1 Case 2 Case 3 Case 4 Case 5 Case 6

17

Chapter 2_Lines and Angles.indd 17 13-08-2024 16:14:27
 Ganita Prakash | Grade 6

Do you see angles being made in each of these cases? Can you mark
their arms and vertex?
Which angle is greater—the angle in Case 1 or the angle in Case 2?
Just as we talk about the size of a line based on its length, we also
talk about the size of an angle based on its amount of rotation.
So, the angle in Case 2 is greater as in this case she needs to rotate
the cover more. Similarly, the angle in Case 3 is even larger than that
of Case 2, because there is even more rotation, and Cases 4, 5, and 6
are successively larger angles with more and more rotation.

The size of an angle is the amount of rotation or turn that is needed
about the vertex to move the first ray to the second ray.
Final position of ray

Amount of turn is the size of
the angle

Vertex Initial position of ray
Fig. 2.9

Let’s look at some other examples where angles arise in real life
by rotation or turn:
In a compass or divider, we turn the arms to form
an angle. The vertex is the point where the two
arms are joined. Identify the arms and vertex of
the angle.
A pair of scissors has two blades. When we open
them (or ‘turn them’) to cut something, the blades
form an angle. Identify the arms and the vertex of
the angle.

18

Chapter 2_Lines and Angles.indd 18 13-08-2024 16:14:27
 Lines and Angles

Look at the pictures of spectacles, wallet and other common
objects. Identify the angles in them by marking out their arms
and vertices.

Do you see how these angles are formed by turning one arm with
respect to the other?

Teacher’s Note
Teacher needs to organise various activities with the students to
recognise the size of an angle as a measure of rotation.

Figure it Out
1. Can you find the angles in the given pictures? Draw the rays
forming any one of the angles and name the vertex of the angle.

B C

A D

19

Chapter 2_Lines and Angles.indd 19 13-08-2024 16:14:28
 Ganita Prakash | Grade 6

2. Draw and label an angle with arms ST and SR.

3. Explain why ∠APC cannot be labelled as ∠P.

Math
A Talk

P B

C

4. Name the angles marked in the given figure.

P
Q

T R

5. Mark any three points on your paper that are not on one line. Label
them A, B, C. Draw all possible lines going through pairs of these
points. How many lines do you get? Name them. How many angles
can you name using A, B, C? Write them down, and mark each of
them with a curve as in Fig. 2.9.

20

Chapter 2_Lines and Angles.indd 20 13-08-2024 16:14:28
 Lines and Angles

6. Now mark any four points on your paper so that no three of them
are on one line. Label them A, B, C, D. Draw all possible lines going
through pairs of these points. How many lines do you get? Name
them. How many angles can you name using A, B, C, D? Write them
all down, and mark each of them with a curve as in Fig. 2.9.

2.6 Comparing Angles
Look at these animals opening their mouths. Do you see any angles
here? If yes, mark the arms and vertex of each one. Some mouths are
open wider than others; the more the turning of the jaws, the larger
the angle! Can you arrange the angles in this picture from smallest to
largest?

Is it always easy to compare two angles?

Math
Talk

Here are some angles. Label each of the angles. How will you
compare them?
Draw a few more angles; label them and compare.

21

Chapter 2_Lines and Angles.indd 21 13-08-2024 16:14:28
 Ganita Prakash | Grade 6

Comparing angles by superimposition
Any two angles can be compared by placing them one over the other,
i.e., by superimposition. While superimposing, the vertices of the
angles must overlap.
After superimposition, it becomes clear which angle is smaller
and which is larger.

P P
A A

B C Q R Q (B) RC

The picture shows the two angles superimposed. It is now clear
that ∠PQR is larger than ∠ABC.
Equal angles. Now consider ∠AOB and ∠XOY in the figure. Which
is greater?
X X
A A

O B O Y O B Y

The corners of both of these angles match and the arms overlap with
each other, i.e., OA ↔ OX and OB ↔ OY. So, the angles are equal in size.
The reason these angles are considered to be equal in size is
because when we visualise each of these angles as being formed out
of rotation, we can see that there is an equal amount of rotation
needed to move OB to OA and OY to OX.
From the point of view of superimposition, when two angles
are superimposed, and the common vertex and the two rays of
both angles lie on top of each other, then the sizes of the angles
are equal.

22

Chapter 2_Lines and Angles.indd 22 13-08-2024 16:14:29
 Lines and Angles

Where else do we use superimposition to compare? Math
Talk
Figure it Out

1. Fold a rectangular sheet of paper, then draw a line along the fold
created. Name and compare the angles
formed between the fold and the sides
of the paper. Make different angles by
folding a rectangular sheet of paper and
compare the angles. Which is the largest
and smallest angle you made?
2. In each case, determine which angle is
greater and why.
a. ∠AOB or ∠XOY X
b. ∠AOB or ∠XOB
A Y
c. ∠XOB or ∠XOC
Discuss with your friends on how
O C
you decided which one is greater. B
Math
3. Which angle is greater: ∠XOY or ∠AOB? Give reasons. Talk

X A
Y

O B

Comparing angles without superimposition
Two cranes are arguing
about who can open their
mouth wider, i.e., who is
making a bigger angle.
Let us first draw their
angles. How do we know
which one is bigger? As seen Fig. 2.10

23

Chapter 2_Lines and Angles.indd 23 13-08-2024 16:14:29
 Ganita Prakash | Grade 6

before, one could trace these angles, superimpose them and then
check. But can we do it without superimposition?
Suppose we have a transparent circle which can be moved and
placed on figures. Can we use this for comparison?
Let us place the circular paper on the angle made by the first
crane. The circle is placed in such a way that its centre is on the
vertex of the angle. Let us mark the points A and B on the edge circle
at the points where the arms of the angle pass through the circle.

B
B

O O

A A

Can we use this to find out if this angle is greater than, or equal to
or smaller than the angle made by the second crane?
Let us place it on the angle made by the second crane so that the
vertex coincides with the centre of the circle and one of the arms
passes through OA.

B Y

O

A
X

Can you now tell
which angle is bigger?

24

Chapter 2_Lines and Angles.indd 24 13-08-2024 16:14:29
 Lines and Angles

Which crane was making the bigger angle?
If you can make a circular piece of transparent paper, try this method
to compare the angles in Fig. 2.10 with each other.

Teacher’s Note
A teacher needs to check the understanding of the students around
the notion of an angle. Sometimes students might think that
increasing the length of the arms of the angle increases the angle.
For this, various situations should be posed to the students to check
their understanding on the same.

2.7 Making Rotating Arms
Let us make ‘rotating arms’ using two paper straws and a paper clip
by following these steps:
1. Take two paper straws and a paper clip. 

2. Insert the straws into the arms of the paper
clip.

3. Your rotating arm is ready!

Make several ‘rotating arms’ with different angles between the
arms. Arrange the angles you have made from smallest to largest by
comparing and using superimposition.
Passing through a slit: Collect a number of rotating arms with different
angles; do not rotate any of the rotating arms during this activity.

25

Chapter 2_Lines and Angles.indd 25 13-08-2024 16:14:30
 Ganita Prakash | Grade 6

Take a cardboard and make an angle-shaped slit as shown below
by tracing and cutting out the shape of one of the rotating arms.

Now, shuffle and mix up all the rotating arms. Can you identify
which of the rotating arms will pass through the slit?
The correct one can be found by placing each of the rotating arms
over the slit. Let us do this for some of the rotating arms:

Slit angle is greater than Slit angle is less than the Slit angle is equal to the
the arms’ angle. The arms arms’ angle. The arms arms’ angle. The arms will
will not go through the will not go through the go through the slit.
slit. slit.

Only the pair of rotating arms where the angle is equal to that of the
slit passes through the slit. Note that the possibility of passing through
the slit depends only on the angle between the rotating arms and not
on their lengths (as long as they are shorter than the length of the slit).

26

Chapter 2_Lines and Angles.indd 26 13-08-2024 16:14:31
 Lines and Angles

Challenge: Reduce
this angle. Angle The angle is still
reduced. the same!

2.8 Special Types of Angles
Let us go back to Vidya’s
notebook and observe her
opening the cover of the book
in different scenarios.
She makes a full turn of the
cover when she has to write
while holding the book in
her hand.
She makes a half turn of the
cover when she has to open
it on her table. In this case,
observe the arms of the angle formed. They lie in a straight line.
Such an angle is called a straight angle.

A O B

Let us consider a straight angle ∠AOB. Observe that any ray OC
divides it into two angles, ∠AOC and ∠COB.

27

Chapter 2_Lines and Angles.indd 27 13-08-2024 16:14:33
 Ganita Prakash | Grade 6

Is it possible to draw OC such that the two angles are Math
equal to each other in size? Talk

Let’s Explore
We can try to solve this problem using a piece of paper. Recall that when
a fold is made, it creates a crease which is straight.
Take a rectangular piece of paper and on one of its sides, mark
the straight angle AOB. By folding, try to get a line (crease) passing
through O that divides ∠AOB into two equal angles.
How can it be done?

Fold the paper such that OB overlaps with OA. Observe the crease
and the two angles formed.

28

Chapter 2_Lines and Angles.indd 28 13-08-2024 16:14:33
 Lines and Angles

Justify why the two angles are equal. Is there a way to
superimpose and check? Can this superimposition be done by
folding?
Each of these equal angles formed are called right angles. So, a
straight angle contains two right angles.

Because they're
Why shouldn't you
always right.
argue with a 90 ̊
angle?

If a straight angle is formed by half of a full turn, how much of a
full turn will form a right angle? 
Observe that a right angle resembles the shape of an ‘L’. An angle
is a right angle only if it is exactly half of a straight angle. Two lines
that meet at right angles are called perpendicular lines.

Figure it Out
1. How many right angles do the windows of your classroom
contain? Do you see other right angles in your classroom?

29

Chapter 2_Lines and Angles.indd 29 13-08-2024 16:14:33
 Ganita Prakash | Grade 6

2. Join A to other grid points in the figure by a straight line to get a
straight angle. What are all the different ways of doing it?

A B A

B

3. Now join A to other grid points in the figure by a straight line to
get a right angle. What are all the different ways of doing it?

A B A

B

Hint: Extend the line further as shown in the figure below. To get
a right angle at A, we need to draw a line through it that
divides the straight angle CAB into two equal parts.

C

A

B

30

Chapter 2_Lines and Angles.indd 30 13-08-2024 16:14:33
 Lines and Angles

4. Get a slanting crease on the paper. Now, try to get another crease
that is perpendicular to the slanting crease.
a. H
 ow many right angles do you have now? Justify why the
angles are exact right angles.
b. D
 escribe how you folded the paper so that any other person
who doesn’t know the process can simply follow your
description to get the right angle.

Classifying Angles
Angles are classified in three groups as shown below. Right angles
are shown in the second group. What could be the common feature
of the other two groups?

In the first group, all angles are less than a right angle or in other
words, less than a quarter turn. Such angles are called acute angles.
In the third group, all angles are greater than a right angle but
less than a straight angle. The turning is more than a quarter turn
and less than a half turn. Such angles are called obtuse angles.

Figure it Out

1. Identify acute, right, obtuse and straight angles in the previous
figures.
2. Make a few acute angles and a few obtuse angles. Draw them in
different orientations.

31

Chapter 2_Lines and Angles.indd 31 13-08-2024 16:14:34
 Ganita Prakash | Grade 6

3. Do you know what the words acute and obtuse mean? Acute means
sharp and obtuse means blunt. Why do you think these words have
been chosen?
4. Find out the number of acute angles in each of the figures below.

What will be the next figure and how many acute angles will it have?
Do you notice any pattern in the numbers?

2.9 Measuring Angles
We have seen how to compare two angles. But can we actually
quantify how big an angle is using a number without having to
compare it to another angle?
We saw how various angles can be compared using a circle.
Perhaps a circle could be used to assign measures for angles?

Fig. 2.12

To assign precise measures to angles, mathematicians came up
with an idea. They divided the angle in the centre of the circle into

32

Chapter 2_Lines and Angles.indd 32 13-08-2024 16:14:34
 Lines and Angles

360 equal angles or parts. The angle measure of each of these unit
parts is 1 degree, which is written as 1°.
This unit part is used to assign measure to any angle: the measure
of an angle is the number of 1° unit parts it contains inside it.
For example, see this figure:

30 units

It contains 30 units of 1° angle and so we say that its angle measure is 30°.
Measures of different angles: What is the measure of a full turn in
degrees? As we have taken it to contain 360 degrees, its measure is 360°.
What is the measure of a straight angle in degrees? A straight
angle is half of a full turn. As a full-turn is 360°, a half turn is 180°.
What is the measure of a right angle in degrees? Two right angles
together form a straight angle. As a straight angle measures 180°, a
right angle measures 90°.
180 units

A O B A O B

A
A

90 units

O B O B

A pinch of history
A full turn has been divided into 360°. Why 360? The reason why
we use 360° today is not fully known. The division of a circle into

33

Chapter 2_Lines and Angles.indd 33 14-08-2024 14:20:43
 Ganita Prakash | Grade 6

360 parts goes back to ancient times. The Rigveda, one of the very
oldest texts of humanity going back thousands of years, speaks of
a wheel with 360 spokes (Verse 1.164.48). Many ancient calendars,
also going back over 3000 years—such as calendars of India, Persia,
Babylonia and Egypt—were based on having 360 days in a year. In
addition, Babylonian mathematicians frequently used divisions of 60
and 360 due to their use of sexagesimal numbers and counting by 60s.
Perhaps the most important and practical answer for why
mathematicians over the years have liked and continued to use 360
degrees is that 360 is the smallest number that can be evenly divided
by all numbers up to 10, aside from 7. Thus, one can break up the
circle into 1, 2, 3, 4, 5, 6, 8, 9 or 10 equal parts, and still have a whole
number of degrees in each part! Note that 360 is also evenly divisible
by 12, the number of months in a year, and by 24, the number of
hours in a day. These facts all make the number 360 very useful.

The circle has been divided into 1, 2, 3, 4, 5, 6, 8, 9 10 and 12 parts
below. What are the degree measures of the resulting angles? Write
the degree measures down near the indicated angles.

Degree measures of different angles
How can we measure other angles in degrees? It is for this purpose
that we have a tool called a protractor that is either a circle divided
into 360 equal parts as shown in Fig. 2.12 (on page 32), or a half
circle divided into 180 equal parts.

34

Chapter 2_Lines and Angles.indd 34 14-08-2024 14:20:57
 Lines and Angles

Unlabelled protractor
Here is a protractor. Do you see the straight angle at the center
divided into 180 units of 1
degree? Only part of the
lines dividing the straight
angle are visible, though!
Starting from the
marking on the rightmost
point of the base, there
is a long mark for every
10°. From every such long
mark, there is a medium
sized mark after 5°.

Figure it out

1. Write the measures of the
following angles:
K
a. ∠ KAL
Notice that the vertex of this
angle coincides with the centre of
L the protractor. So the number of
units of 1 degree angle between KA
A and AL gives the measure of ∠KAL.
By counting, we get —
∠KAL = 30°
Making use of the medium sized
and large sized marks, is it possible
to count the number of units in 5s
or 10s?
W
b. ∠WAL
c. ∠TAK
T

35

Chapter 2_Lines and Angles.indd 35 13-08-2024 16:14:34
 Ganita Prakash | Grade 6

Labelled protractor
This is a protractor that you find in your geometry box. It would
appear similar to the protractor above except that there are numbers
written on it. Will these make it easier to read the angles?

80 90 100
70 110
100 90 80 12
60 70 0
110 13
0 60
50 12 0
30 50
1

14
40

0
0

40
14

15
30

0
0

30
15

160
20
160

20

170
10
170

10
180

180
0

0
There are two sets of numbers on the protractor: one increasing
from right to left and the other increasing from left to right. Why
does it include two sets of numbers?

Name the different angles in the figure and write their measures.
R

S

80 90 100
70 110
100 90 80 12
60 70 0
110
50 12
0 60 13
0 Q
0 50
13
14
40

0
0

40
14

T
15
30

0
0

30
15

160
20
160

20

170
10
170

10

P
U
180

180
0

0

O

36

Chapter 2_Lines and Angles.indd 36 13-08-2024 16:14:35
 Lines and Angles

Did you include angles such as ∠TOQ?
Which set of markings did you use — inner or outer?
What is the measure of ∠TOS?
Can you use the numbers marked to find the angle without
counting the number of markings?
Here, OT and OS pass through the numbers 20 and 55 on the outer
scale. How many units of 1 degree are contained between these
two arms?
Can subtraction be used here?
How can we measure angles directly without having to subtract?
Place the protractor so the center is on the vertex of the angle.
Align the protractor so that one the arms passes through the 0º
mark as in the picture below.
A
80 90 100
70 110
100 90 80 12
60 70 0
110 13
0 60
50 12 0
30 50
1
14
40

0
0

40
14

15
30

0
0

30
15

160
20
160

20

170
10
170

10
180

180
0

0

O B
What is the degree measure of ∠AOB?
Make your own Protractor!
You may have wondered how the different equally spaced markings are
made on a protractor. We will now see how we can make some of them!
1. Draw a circle of a convenient radius on a sheet of paper. Cut out
the circle (Fig. 2.13). A circle or one full turn is 360°.
2. Fold the circle to get two equal halves and cut it through the
crease to get a semicircle. Write ‘0°’ in the bottom right corner of
the semicircle.

37

Chapter 2_Lines and Angles.indd 37 13-08-2024 16:14:35
 Ganita Prakash | Grade 6

Fig. 2.13

The measure of half
1
a circle is 2 of a full
turn. (Fig. 2.14)
180 units
So, the measure of
1
half a turn = 2 of ____
= 180°. A O B
Fig. 2.14 Thus, write 180° in
the left bottom corner
of the semicircle.

3. Fold the semi-circular sheet in half as shown in Fig. 2.15 to form
a quarter circle.

The measure of a
1
quarter circle is 4 of a
full turn.
The measure of a A
1 1
4 turn = 4 of 360° =
________. 90 units
1
Or, the measure of a 4
1
turn = 2 of a half turn O B
1
= 2 of 180° = ______.
Thus, mark 90° at the
Fig. 2.15
top of the semicircle.

38

Chapter 2_Lines and Angles.indd 38 13-08-2024 16:14:35
 Lines and Angles

4. Fold the sheet again as shown in Figs. 2.16 and 2.17:

90O

135O 45O

180O 0O
Fig. 2.16 Fig. 2.17

When folded, this is 18 of the circle, or 18 of a turn, or 18 of 360°,
or 14 of 180° or 12 of 90° = ________________________.
The new creases formed give us measures of 45° and
180°−  45° = 135° as shown. Write 45° and 135° at the correct
places on the new creases along the edge of the semicircle.
5. Continuing with another half fold as shown in Fig. 2.18, we get
an angle of measure ________________________.

Fig. 2.18

6. Unfold and mark the creases as OB, OC,..., etc., as shown in
Fig. 2.19 and Fig. 2.20.

E
F D
90O
112

5O

G C 135O.5

67.
O

45O
H B 157.5 O O
5
22.
180O 0O
I A
O
Fig. 2.20
Fig. 2.19

39

Chapter 2_Lines and Angles.indd 39 13-08-2024 16:14:35
 Ganita Prakash | Grade 6

Think!
I n Fig. 2.20, we have ∠AOB = ∠BOC = ∠COD = ∠DOE = ∠EOF = ∠FOG =
∠GOH = ∠HOI=_____. Why?

Angle Bisector
At each step, we folded in halves. This process of getting half of a
given angle is called bisecting the angle. The line that bisects a given
angle is called the angle bisector of the angle.
Identify the angle bisectors in your handmade protractor. Try to make
different angles using the concept of angle bisector through paper folding.

Figure it Out

1. Find the degree measures of the following angles using your
protractor.
H
I
I

J H

J
J
I
H
G K

2. Find the degree measures of different angles in your classroom
using your protractor.

Teacher’s Note
It is important that students make their own protractor and use it to
measure different angles before using the standard protractor so that
they know the concept behind the marking of the standard protractor.

40

Chapter 2_Lines and Angles.indd 40 13-08-2024 16:14:35
 Lines and Angles

3. Find the degree measures for the angles given below. Check if
your paper protractor can be used here!

H I H
c
J

J I

4. How can you find the degree measure of the angle given below
using a protractor?

5. Measure and write the degree measures for each of the following
angles:

a. b.

41

Chapter 2_Lines and Angles.indd 41 13-08-2024 16:14:36
 Ganita Prakash | Grade 6

c.
d.

e. f.

6. Find the degree measures of ∠BXE, ∠CXE, ∠AXB and ∠BXC.

C
B
90
70
80 A 100
110
100 90 80 12
60 70 0
110 13
20 60
50 1 0
0 50
13
14
40

0
0

40
14

15
30

0
0

30
15

160
20
160

20

170
10
170

10

B
180

180
0

0

A X E

7. Find the degree measures of ∠PQR, ∠PQS and ∠PQT.

S
R

T
P

Q

42

Chapter 2_Lines and Angles.indd 42 13-08-2024 16:14:36
 Lines and Angles

8. Make the paper craft as per the given instructions. Then, unfold
and open the paper fully. Draw lines on the creases made and
measure the angles formed.

1 2 3 4

5 6 8
7

9. Measure all three angles of the triangle shown in Fig. 2.21 (a), and
write the measures down near the respective angles. Now add up
the three measures. What do you get? Do the same for the triangles
in Fig. 2.21 (b) and (c). Try it for other triangles as well, and then
make a conjecture for what happens in general! We will come back
to why this happens in a later year.

C A
A

B

B

A C
B C
(a) (b) (c)

Fig. 2.21

43

Chapter 2_Lines and Angles.indd 43 13-08-2024 16:14:36
 Ganita Prakash | Grade 6

Mind the Mistake, Mend the Mistake!
A student used a protractor to measure the angles as shown below.
In each figure, identify the incorrect usage(s) of the protractor and
discuss how the reading could have been made and think how it can
be corrected.

∠V = 80⁰
∠U = 35⁰
80 90 100 50 60 70
110 80
70 40
90 80 12 120 110 90
60 100 0 130 100
110 70 30 140 10
60 13 90 0
50 1 20 0 0
50 20 15 80
0
13 0
16

11
14
40

0
0

10

70
0

40
14

0

12
17
15
30

0
0
0

60
30

0
15

180

130
160
20
160

50
20

140
170
10
170

10

40
180

180

150
V

30
0

0

U

20

160
10

170
0

180
∠X = 150⁰
110
∠W = 70⁰
100 120
90 130
80 80 70 60 14
80 90 100 90 50 0
110
70 70 100 40 15
100 90 80 12 0 0
60 70 0 11
110 30
60

0 60 13
50 12 0

16
0
12

50

0
0
13

20
50