Understanding Quadrilaterals Class 3 Math PDF

Summary

This document covers the topic of quadrilaterals, including convex and concave polygons, as well as regular and irregular polygons. The provided text contains definitions, examples, and exercises related to these topics.

Full Transcript

UNDERSTANDING QUADRILATERALS 21
CHAPTER
Understanding
Quadrilaterals
3
3.1 Introduction
You know that the paper is a model for a plane surface. When you join a number of
points without lifting a pencil from the paper (and without retracing any portion of the
drawing other than single points), you get a plane curve.

3.1.1 Convex and concave polygons
A simple closed curve made up of only line segments is called a polygon.

Curves that are polygons Curves that are not polygons
Here are some convex polygons and some concave polygons. (Fig 3.1)

Convex polygons Concave polygons
Fig 3.1
Can you find how these types of polygons differ from one another? Polygons that are
convex have no portions of their diagonals in their exteriors or any line segment joining any
two different points, in the interior of the polygon, lies wholly in the interior of it. Is this
true with concave polygons? Study the figures given. Then try to describe in your own
words what we mean by a convex polygon and what we mean by a concave polygon. Give
two rough sketches of each kind.
In our work in this class, we will be dealing with convex polygons only.
3.1.2 Regular and irregular polygons
A regular polygon is both ‘equiangular’ and ‘equilateral’. For example, a square has sides
of equal length and angles of equal measure. Hence it is a regular polygon. A rectangle is

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22 MATHEMATICS

equiangular but not equilateral. Is a rectangle a regular polygon? Is an equilateral triangle a
regular polygon? Why?

Regular polygons Polygons that are not regular

[Note: Use of or indicates segments of equal length].
In the previous classes, have you come across any quadrilateral that is equilateral but not
equiangular? Recall the quadrilateral shapes you saw in earlier classes – Rectangle, Square,
Rhombus etc.
Is there a triangle that is equilateral but not equiangular?

EXERCISE 3.1
1. Given here are some figures.

(1) (2) (3) (4)

(5) (6) (7) (8)
Classify each of them on the basis of the following.
(a) Simple curve (b) Simple closed curve (c) Polygon
(d) Convex polygon (e) Concave polygon
2. What is a regular polygon?
State the name of a regular polygon of
(i) 3 sides (ii) 4 sides (iii) 6 sides

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 UNDERSTANDING QUADRILATERALS 23

3.2 Sum of the Measures of the Exterior Angles of a
Polygon
On many occasions a knowledge of exterior angles may throw light on the nature of interior
angles and sides.

DO THIS

Draw a polygon on the floor, using a piece of chalk.
(In the figure, a pentagon ABCDE is shown) (Fig 3.2).
We want to know the total measure of angles, i.e,
m∠1 + m∠2 + m∠3 + m∠4 + m∠5. Start at A. Walk along
AB. On reaching B, you need to turn through an angle of m∠1,
to walk along. BC When you reach at C, you need to turn
through an angle of m∠2 to walk along CD. You continue to
move in this manner, until you return to side AB. You would
have in fact made one complete turn. Fig 3.2
Therefore, m∠1 + m∠2 + m∠3 + m∠4 + m∠5 = 360°.
This is true whatever be the number of sides of the polygon.
Therefore, the sum of the measures of the external angles of any polygon is 360°.

Example 1: Find measure x in Fig 3.3.
Solution: x + 90° + 50° + 110° = 360° (Why?)
x + 250° = 360°
x = 110°

TRY THESE Fig 3.3

Take a regular hexagon Fig 3.4.
1. What is the sum of the measures of its exterior angles x, y, z, p, q, r?
2. Is x = y = z = p = q = r? Why?
3. What is the measure of each?
(i) exterior angle (ii) interior angle
4. Repeat this activity for the cases of
(i) a regular octagon (ii) a regular 20-gon Fig 3.4

Example 2: Find the number of sides of a regular polygon whose each exterior angle
has a measure of 45°.
Solution: Total measure of all exterior angles = 360°
Measure of each exterior angle = 45°
360
Therefore, the number of exterior angles = =8
45
The polygon has 8 sides.

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24 MATHEMATICS

EXERCISE 3.2
1. Find x in the following figures.

(a) (b)
2. Find the measure of each exterior angle of a regular polygon of
(i) 9 sides (ii) 15 sides
3. How many sides does a regular polygon have if the measure of an exterior angle is 24°?
4. How many sides does a regular polygon have if each of its interior angles
is 165°?
5. (a) Is it possible to have a regular polygon with measure of each exterior angle as 22°?
(b) Can it be an interior angle of a regular polygon? Why?
6. (a) What is the minimum interior angle possible for a regular polygon? Why?
(b) What is the maximum exterior angle possible for a regular polygon?

3.3 Kinds of Quadrilaterals
Based on the nature of the sides or angles of a quadrilateral, it gets special names.
3.3.1 Trapezium
Trapezium is a quadrilateral with a pair of parallel sides.

These are trapeziums These are not trapeziums
Study the above figures and discuss with your friends why some of them are trapeziums
while some are not. (Note: The arrow marks indicate parallel lines).

DO THIS
1. Take identical cut-outs of congruent triangles of sides 3 cm, 4 cm, 5 cm. Arrange
them as shown (Fig 3.5).

Fig 3.5

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 UNDERSTANDING QUADRILATERALS 25

You get a trapezium. (Check it!) Which are the parallel sides here? Should the
non-parallel sides be equal?
You can get two more trapeziums using the same set of triangles. Find them out and
discuss their shapes.
2. Take four set-squares from your and your friend’s instrument boxes. Use different
numbers of them to place side-by-side and obtain different trapeziums.
If the non-parallel sides of a trapezium are of equal length, we call it an isosceles
trapezium. Did you get an isoceles trapezium in any of your investigations given above?

3.3.2 Kite
Kite is a special type of a quadrilateral. The sides with the same markings in each figure
are equal. For example AB = AD and BC = CD.

These are kites These are not kites
Study these figures and try to describe what a kite is. Observe that
(i) A kite has 4 sides (It is a quadrilateral).
(ii) There are exactly two distinct consecutive pairs of sides of equal length.
Check whether a square is a kite.

DO THIS Show that
∆ABC and
Take a thick white sheet. ∆ADC are
Fold the paper once. congruent.
Draw two line segments of different lengths as shown in Fig 3.6. What do we
Cut along the line segments and open up. infer from
this?
You have the shape of a kite (Fig 3.6).
Has the kite any line symmetry? Fig 3.6
Fold both the diagonals of the kite. Use the set-square to check if they cut at
right angles. Are the diagonals equal in length?
Verify (by paper-folding or measurement) if the diagonals bisect each other.
By folding an angle of the kite on its opposite, check for angles of equal measure.
Observe the diagonal folds; do they indicate any diagonal being an angle bisector?
Share your findings with others and list them. A summary of these results are
given elsewhere in the chapter for your reference. Fig 3.7

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26 MATHEMATICS

3.3.3 Parallelogram
A parallelogram is a quadrilateral. As the name suggests, it has something to do with
parallel lines.

AB
DC
AD
BC AB
CD

LM
ON
QP
SR AB
ED
LO
MN
QS
PR BC
FE

These are parallelograms These are not parallelograms
Study these figures and try to describe in your own words what we mean by a
parallelogram. Share your observations with your friends.
Check whether a rectangle is also a parallelogram.

DO THIS
Take two different rectangular cardboard strips of different widths (Fig 3.8).

Strip 1 Fig 3.8 Strip 2

Place one strip horizontally and draw lines along
its edge as drawn in the figure (Fig 3.9).
Now place the other strip in a slant position over
the lines drawn and use this to draw two more lines
Fig 3.9
as shown (Fig 3.10).
These four lines enclose a quadrilateral. This is made up of two pairs of parallel lines
(Fig 3.11).

Fig 3.10 Fig 3.11

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 UNDERSTANDING QUADRILATERALS 27

It is a parallelogram.
A parallelogram is a quadrilateral whose opposite sides are parallel.
3.3.4 Elements of a parallelogram
There are four sides and four angles in a parallelogram. Some of these are
equal. There are some terms associated with these elements that you need
to remember.
Fig 3.12
Given a parallelogram ABCD (Fig 3.12).
AB and DC , are opposite sides. AD and BC form another pair of opposite sides.
∠A and ∠C are a pair of opposite angles; another pair of opposite angles would be
∠B and ∠D.
AB and BC are adjacent sides. This means, one of the sides starts where the other
ends. Are BC and CD adjacent sides too? Try to find two more pairs of adjacent sides.
∠A and ∠B are adjacent angles. They are at the ends of the same side. ∠B and ∠C
are also adjacent. Identify other pairs of adjacent angles of the parallelogram.

DO THIS
Take cut-outs of two identical parallelograms, say ABCD and A′B′C′D′ (Fig 3.13).

Fig 3.13
Here AB is same as A′ B′ except for the name. Similarly the other corresponding
sides are equal too.
Place A ′ B′ over DC. Do they coincide? What can you now say about the lengths
AB and DC ?
Similarly examine the lengths AD and BC. What do you find?
You may also arrive at this result by measuring AB and DC.

Property: The opposite sides of a parallelogram are of equal length.
TRY THESE
Take two identical set squares with angles 30° – 60° – 90°
and place them adjacently to form a parallelogram as shown
in Fig 3.14. Does this help you to verify the above property?
You can further strengthen this idea
through a logical argument also.
Consider a parallelogram
ABCD (Fig 3.15). Draw
any one diagonal, say AC. Fig 3.15 Fig 3.14

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28 MATHEMATICS

Looking at the angles,
∠1 = ∠2 and ∠3 = ∠4 (Why?)
Since in triangles ABC and ADC, ∠1 = ∠2, ∠3 = ∠4
and AC is common, so, by ASA congruency condition,
∆ ABC ≅ ∆ CDA (How is ASA used here?)
This gives AB = DC and BC = AD.
Example 3: Find the perimeter of the parallelogram PQRS (Fig 3.16).
Solution: In a parallelogram, the opposite sides have same length.
Therefore, PQ = SR = 12 cm and QR = PS = 7 cm
So, Perimeter = PQ + QR + RS + SP
= 12 cm + 7 cm + 12 cm + 7 cm = 38 cm
Fig 3.16
3.3.5 Angles of a parallelogram
We studied a property of parallelograms concerning the (opposite) sides. What can we
say about the angles?

DO THIS
Let ABCD be a parallelogram (Fig 3.17). Copy it on
a tracing sheet. Name this copy as A′B′C′D′. Place
A′B′C′D′ on ABCD. Pin them together at the point
where the diagonals meet. Rotate the transparent sheet
by 180°. The parallelograms still concide; but you now
find A′ lying exactly on C and vice-versa; similarly B′
lies on D and vice-versa.
Fig 3.17

Does this tell you anything about the measures of the angles A and C? Examine the
same for angles B and D. State your findings.
Property: The opposite angles of a parallelogram are of equal measure.

TRY THESE
Take two identical 30° – 60° – 90° set-squares and form a parallelogram as before.
Does the figure obtained help you to confirm the above property?

You can further justify this idea through logical arguments.
If AC and BD are the diagonals of the
parallelogram, (Fig 3.18) you find that
∠1 =∠2 and ∠3 = ∠4 (Why?) Fig 3.18

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 UNDERSTANDING QUADRILATERALS 29

Studying ∆ ABC and ∆ ADC (Fig 3.19) separately, will help you to see that by ASA
congruency condition,
∆ ABC ≅ ∆ CDA(How?)

Fig 3.19
This shows that ∠B and ∠D have same measure. In the same way you can get
m∠A = m ∠C.
Alternatively, ∠1 = ∠2 and ∠3 = ∠4, we have, m∠A = ∠1+∠4 = ∠2+∠C m∠C
Example 4: In Fig 3.20, BEST is a parallelogram. Find the values x, y and z.
Solution: S is opposite to B.
So, x = 100° (opposite angles property)
y = 100° (measure of angle corresponding to ∠x)
z = 80° (since ∠y, ∠z is a linear pair)
We now turn our attention to adjacent angles of a parallelogram.
In parallelogram ABCD, (Fig 3.21). Fig 3.20
∠A and ∠D are supplementary since
DC
AB and with transversal DA , these
two angles are interior opposite.
∠A and ∠B are also supplementary. Can you
Fig 3.21
say ‘why’?
AD
BC and BA is a transversal, making ∠A and ∠B interior opposite.
Identify two more pairs of supplementary angles from the figure.
Property: The adjacent angles in a parallelogram are supplementary.
Example 5: In a parallelogram RING, (Fig 3.22) if m∠R = 70°, find all the other angles.
Solution: Given m∠R = 70°
Then m∠N = 70°
because ∠R and ∠N are opposite angles of a parallelogram.
Since ∠R and ∠I are supplementary,
m∠I = 180° – 70° = 110° Fig 3.22
Also, m∠G = 110° since ∠G is opposite to ∠I
Thus, m∠R = m∠N = 70° and m∠I = m∠G = 110°

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30 MATHEMATICS

THINK, DISCUSS AND WRITE
After showing m∠R = m∠N = 70°, can you find m∠I and m∠G by any other
method?
3.3.6 Diagonals of a parallelogram
The diagonals of a parallelogram, in general, are not of equal length.
(Did you check this in your earlier activity?) However, the diagonals
of a parallelogram have an interesting property.

DO THIS

Take a cut-out of a parallelogram, say,
ABCD (Fig 3.23). Let its diagonals AC and DB meet at O. Fig 3.23
Find the mid point of AC by a fold, placing C on A. Is the
mid-point same as O?
Does this show that diagonal DB bisects the diagonal AC at the point O? Discuss it
with your friends. Repeat the activity to find where the mid point of DB could lie.

Property: The diagonals of a parallelogram bisect each other (at the point of their
intersection, of course!)
To argue and justify this property is not very
difficult. From Fig 3.24, applying ASA criterion, it
is easy to see that
∆ AOB ≅ ∆ COD (How is ASA used here?) Fig 3.24

This gives AO = CO and BO = DO
Example 6: In Fig 3.25 HELP is a parallelogram. (Lengths are in cms). Given that
OE = 4 and HL is 5 more than PE? Find OH.
Solution : If OE = 4 then OP also is 4 (Why?)
So PE = 8, (Why?)
Therefore HL = 8 + 5 = 13
Fig 3.25
1
Hence OH = × 13 = 6.5 (cms)
2

EXERCISE 3.3
1. Given a parallelogram ABCD. Complete each
statement along with the definition or property used.
(i) AD =...... (ii) ∠ DCB =......
(iii) OC =...... (iv) m ∠DAB + m ∠CDA =......

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 UNDERSTANDING QUADRILATERALS 31

2. Consider the following parallelograms. Find the values of the unknowns x, y, z.

(i) (ii)

30

(iii) (iv) (v)
3. Can a quadrilateral ABCD be a parallelogram if
(i) ∠D + ∠B = 180°? (ii) AB = DC = 8 cm, AD = 4 cm and BC = 4.4 cm?
(iii) ∠A = 70° and ∠C = 65°?
4. Draw a rough figure of a quadrilateral that is not a parallelogram but has exactly two opposite angles
of equal measure.
5. The measures of two adjacent angles of a parallelogram are in the ratio 3 : 2. Find the measure of each
of the angles of the parallelogram.
6. Two adjacent angles of a parallelogram have equal measure. Find the
measure of each of the angles of the parallelogram.
7. The adjacent figure HOPE is a parallelogram. Find the angle measures
x, y and z. State the properties you use to find them.
8. The following figures GUNS and RUNS are parallelograms.
Find x and y. (Lengths are in cm)

(i) (ii)

9.

In the above figure both RISK and CLUE are parallelograms. Find the value of x.

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 32 MATHEMATICS

10. Explain how this figure is a trapezium. Which of its two sides are parallel? (Fig 3.26)

Fig 3.26 Fig 3.27
11. Find m∠C in Fig 3.27 if AB
DC.
12. Find the measure of ∠P and ∠S if SP
RQ in Fig 3.28.
(If you find m∠R, is there more than one method to find m∠P?) Fig 3.28

3.4 Some Special Parallelograms
3.4.1 Rhombus
We obtain a Rhombus (which, you will see, is a parallelogram) as a special case of kite
(which is not a a parallelogram).

DO THIS

Recall the paper-cut kite you made earlier.

Kite-cut Rhombus-cut
When you cut along ABC and opened up, you got a kite. Here lengths AB and
BC were different. If you draw AB = BC, then the kite you obtain is called a rhombus.

Note that the sides of rhombus are all of same length;
this is not the case with the kite.
A rhombus is a quadrilateral with sides of equal length.
Since the opposite sides of a rhombus have the same
length, it is also a parallelogram. So, a rhombus has all
the properties of a parallelogram and also that of a
kite. Try to list them out. You can then verify your list
with the check list summarised in the book elsewhere.
Kite Rhombus

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 UNDERSTANDING QUADRILATERALS 33

The most useful property of a rhombus is that of its diagonals.
Property: The diagonals of a rhombus are perpendicular bisectors of one another.

DO THIS
Take a copy of rhombus. By paper-folding verify if the point of intersection is the
mid-point of each diagonal. You may also check if they intersect at right angles, using
the corner of a set-square.

Here is an outline justifying this property using logical steps.
ABCD is a rhombus (Fig 3.29). Therefore it is a parallelogram too.
Since diagonals bisect each other, OA = OC and OB = OD.
We have to show that m∠AOD = m∠COD = 90°
It can be seen that by SSS congruency criterion Fig 3.29
∆ AOD ≅ ∆ COD
Since AO = CO (Why?)
Therefore, m ∠AOD = m ∠COD
AD = CD (Why?)
Since ∠AOD and ∠COD are a linear pair,
OD = OD
m ∠AOD = m ∠COD = 90°
Example 7:
RICE is a rhombus (Fig 3.30). Find x, y, z. Justify your findings.
Solution:
x = OE y = OR z = side of the rhombus
= OI (diagonals bisect) = OC (diagonals bisect) = 13 (all sides are equal )
= 5 = 12 Fig 3.30
3.4.2 A rectangle
A rectangle is a parallelogram with equal angles (Fig 3.31).
What is the full meaning of this definition? Discuss with your friends.
If the rectangle is to be equiangular, what could be
the measure of each angle? Fig 3.31
Let the measure of each angle be x°.
Then 4x° = 360° (Why)?
Therefore, x° = 90°
Thus each angle of a rectangle is a right angle.
So, a rectangle is a parallelogram in which every angle is a right angle.
Being a parallelogram, the rectangle has opposite sides of equal length and its diagonals
bisect each other.

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34 MATHEMATICS

In a parallelogram, the diagonals can be of different lengths. (Check this); but surprisingly
the rectangle (being a special case) has diagonals of equal length.
Property: The diagonals of a rectangle are of equal length.

Fig 3.32 Fig 3.33 Fig 3.34
This is easy to justify. If ABCD is a rectangle (Fig 3.38), then looking at triangles
ABC and ABD separately [(Fig 3.33) and (Fig 3.34) respectively], we have
∆ ABC ≅ ∆ ABD
This is because AB = AB (Common)
BC = AD (Why?)
m ∠A = m ∠B = 90° (Why?)
The congruency follows by SAS criterion.
Thus AC = BD
and in a rectangle the diagonals, besides being equal in length bisect each other (Why?)
Example 8: RENT is a rectangle (Fig 3.35). Its diagonals meet at O. Find x, if
OR = 2x + 4 and OT = 3x + 1.
Solution: OT is half of the diagonal TE ,
OR is half of the diagonal RN.
Diagonals are equal here. (Why?)
So, their halves are also equal.
Therefore 3x + 1 = 2x + 4
or x=3
3.4.3 A square
A square is a rectangle with equal sides. Fig 3.35
This means a square has all the
properties of a rectangle with an additional
requirement that all the sides have equal
length.
The square, like the rectangle, has
diagonals of equal length. BELT is a square, BE = EL = LT = TB
In a rectangle, there is no requirement ∠B, ∠E, ∠L, ∠T are right angles.
for the diagonals to be perpendicular to BL = ET and BL ⊥ ET.
one another, (Check this). OB = OL and OE = OT.

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 UNDERSTANDING QUADRILATERALS 35

In a square the diagonals.
(i) bisect one another (square being a parallelogram)
(ii) are of equal length (square being a rectangle) and
(iii) are perpendicular to one another.
Hence, we get the following property.
Property: The diagonals of a square are perpendicular bisectors of each other.

DO THIS
Take a square sheet, say PQRS (Fig 3.37).
Fold along both the diagonals. Are their mid-points the same?
Check if the angle at O is 90° by using a set-square.
This verifies the property stated above.
Fig 3.36
We can justify this also by arguing logically:
ABCD is a square whose diagonals meet at O (Fig 3.37).
OA = OC (Since the square is a parallelogram)
By SSS congruency condition, we now see that
∆ AOD ≅ ∆ COD (How?)
Therefore, m∠AOD = m∠COD
These angles being a linear pair, each is right angle.
Fig 3.37
EXERCISE 3.4
1. State whether True or False.
(a) All rectangles are squares (e) All kites are rhombuses.
(b) All rhombuses are parallelograms (f) All rhombuses are kites.
(c) All squares are rhombuses and also rectangles (g) All parallelograms are trapeziums.
(d) All squares are not parallelograms. (h) All squares are trapeziums.
2. Identify all the quadrilaterals that have.
(a) four sides of equal length (b) four right angles
3. Explain how a square is.
(i) a quadrilateral (ii) a parallelogram (iii) a rhombus (iv) a rectangle
4. Name the quadrilaterals whose diagonals.
(i) bisect each other (ii) are perpendicular bisectors of each other (iii) are equal
5. Explain why a rectangle is a convex quadrilateral.
6. ABC is a right-angled triangle and O is the mid point of the side
opposite to the right angle. Explain why O is equidistant from A,
B and C. (The dotted lines are drawn additionally to help you).

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36 MATHEMATICS

THINK, DISCUSS AND WRITE
1. A mason has made a concrete slab. He needs it to be rectangular. In what
different ways can he make sure that it is rectangular?
2. A square was defined as a rectangle with all sides equal. Can we define it as
rhombus with equal angles? Explore this idea.
3. Can a trapezium have all angles equal? Can it have all sides equal? Explain.

WHAT HAVE WE DISCUSSED?

Quadrilateral Properties

Parallelogram: (1) Opposite sides are equal.
A quadrilateral (2) Opposite angles are equal.
with each pair of
(3) Diagonals bisect one another.
opposite sides
parallel.

Rhombus: (1) All the properties of a parallelogram.
A parallelogram with sides (2) Diagonals are perpendicular to each other.
of equal length.

Rectangle: (1) All the properties of a parallelogram.
A parallelogram (2) Each of the angles is a right angle.
with a right angle. (3) Diagonals are equal.

Square: A rectangle
with sides of equal All the properties of a parallelogram,
length. rhombus and a rectangle.

Kite: A quadrilateral
with exactly two pairs (1) The diagonals are perpendicular
of equal consecutive to one another
sides (2) One of the diagonals bisects the other.
(3) In the figure m∠B = m∠D but
m∠A ≠ m∠C.

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