vaga study – free pdfsmanufacturers, architects and many others make use of the idea of symmetry....

14.1 INTRODUCTION

Symmetry is an important geometrical concept, commonly exhibited in nature and is used

almost in every field of activity. Artists, professionals, designers of clothing or jewellery, car

manufacturers, architects and many others make use of the idea of symmetry. The beehives,

the flowers, the tree-leaves, religious symbols, rugs, and handkerchiefs — everywhere you

find symmetrical designs.

You have already had a ‘feel’ of line symmetry in your previous class.

A figure has a line symmetry, if there is a line about which the figure may be folded so that

the two parts of the figure will coincide.

You might like to recall these ideas. Here are some activities to help you.

NatureArchitecture Engineering

Create some colourful

Ink-dot devils

Make some symmetrical

paper-cut designs.

Compose a picture-album

showing symmetry.

2019-20

14.1 I


almost in every field of activity

manufacturers, architects and many others make use of the idea of symmetry



You have already had a ‘feel’You have already had a ‘feel’Y


You might like to recall these ideas. Here are some activities to help you.You might like to recall these ideas. Here are some activities to help you.Y

Create some colourful

Ink-dot devils

Make some symmetrical

paper-cut designs.

Compose a picture-album

showing symmetry.

2019-20

14.1 INTRODUCTION


almost in every field of activity. almost in every field of activity. almost in every field of activity Artists, professionals, designers of clothing or jewellery, carArtists, professionals, designers of clothing or jewellery, carArtists, professionals, designers of clothing or jewellery

manufacturers, architects and many others make use of the idea of symmetry. The beehives,



ou have already had a ‘feel’ of line symmetry in your previous class.y in your previous class.yA figure has a line symmetryA figure has a line symmetryA , if there is a line about which the figure may be folded so that figure has a line symmetry, if there is a line about which the figure may be folded so that figure has a line symmetry


ou might like to recall these ideas. Here are some activities to help you.

NatureArchitecture Engineering

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Enjoy identifying lines (also called axes) of symmetry in the designs you collect.

Let us now strengthen our ideas on symmetry further. Study the following figures in

which the lines of symmetry are marked with dotted lines. [Fig 14.1 (i) to (iv)]

14.2 LINES OF SYMMETRY FOR REGULAR POLYGONS

You know that a polygon is a closed figure made of several line segments. The polygon

made up of the least number of line segments is the triangle. (Can there be a polygon that

you can draw with still fewer line segments? Think about it).

A polygon is said to be regular if all its sides are of equal length and all its angles are of

equal measure. Thus, an equilateral triangle is a regular polygon of three sides. Can you

name the regular polygon of four sides?

An equilateral triangle is regular because each of its sides has same length and each of

its angles measures 60° (Fig 14.2).

A square is also regular because all its sides are of equal length and each of its angles

is a right angle (i.e., 90°). Its diagonals are seen to be perpendicular bisectors of one

another (Fig 14.3).

Fig 14.1(i) (ii) (iii) (iv)

60°

60°

60°

a a

a

Fig 14.2

Fig 14.3

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Enjoy identifying lines (also called axes) of symmetry in the designs you collect.

Let us now strengthen our ideas on symmetry further. Study the following figures in

which the lines of symmetry are marked with dotted lines. [Fig 14.1 (i) to (iv)]

ou know that a polygon is a closed figure made of several line segments. The polygon







Fig 14.3

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14.2 LINES OF SOF SOF YMMETRY FOR RFOR RFOR EGULAR PEGULAR PEGULAR OLYGONS

You know that a polygon is a closed figure made of several line segments. The polygonYou know that a polygon is a closed figure made of several line segments. The polygonY


you can draw with still fewer line segments? Think about it).



name the regular polygon of four sides?


its angles measures 60° (Fig 14.2).



another (Fig 14.3).

Fig 14.1(i) (ii) (iii)(iii)( (iv)

60°

60°

60°60°

a a

a

Fig 14.2

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If a pentagon is regular, naturally, its sides should have equal length. You will, later on,

learn that the measure of each of its angles is 108° (Fig 14.4).

A regular hexagon has all its sides equal and each of its angles measures

120°. You will learn more of these figures later (Fig 14.5).

The regular polygons are symmetrical figures and hence their lines of

symmetry are quite interesting,

Each regular polygon has as many lines of symmetry as it has sides [Fig 14.6 (i) - (iv)].

We say, they have multiple lines of symmetry.

Perhaps, you might like to investigate this by paper folding. Go ahead!

The concept of line symmetry is closely related to mirror reflection. A shape has line

symmetry when one half of it is the mirror image of the other half (Fig 14.7). A mirror line,

thus, helps to visualise a line of symmetry (Fig 14.8).

Is the dotted line a mirror line? No. Is the dotted line a mirror line? Yes.

Fig 14.8

Fig 14.4

Fig 14.5

Fig 14.7

Fig 14.6

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If a pentagon is regular, naturally, its sides should have equal length. You will, later on,You will, later on,Y

learn that the measure of each of its angles is 108° (Fig 14.4).

120°.


We sayWe sayW


symmetry when one half of it is the mirror image of the other half (Fig 14.7).


Is the dotted line a mirror line? No. Is the dotted line a mirror line? Yes.Yes.Y

Fig 14.8

Fig 14.7

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A regular hexagon has all its sides equal and each of its angles measures

120°. You will learn more of these figures later (Fig 14.5).You will learn more of these figures later (Fig 14.5).Y

The regular polygons are symmetrical figures and hence their lines of


Each regular polygon has as many lines of symmetry as it has sides [Fig 14.6 (i) - (iv)].

e say, they have multiple lines of symmetry., they have multiple lines of symmetry., they have multiple lines of symmetry


The concept of line symmetry is closely related to mirror reflection. A shape has lineA shape has lineA

symmetry when one half of it is the mirror image of the other half (Fig 14.7). A mirror line,A mirror line,A


Fig 14.4

Fig 14.5

Fig 14.7

Fig 14.6

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While dealing with mirror reflection, care is needed to note down the left-right changes

in the orientation, as seen in the figure here (Fig 14.9).

The shape is same, but the other way round!

Play this punching game!

Fold a sheet into two halves Punch a hole two holes about the

symmetric fold.

Fig 14.10The fold is a line (or axis) of symmetry. Study about punches at different locations on

the folded paper and the corresponding lines of symmetry (Fig 14.10).

EXERCISE 14.1

1. Copy the figures with punched holes and find the axes of symmetry for the following:

(i) (ii)Fig 14.9

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While dealing with mirror reflection, care is needed to note down the left-right changes


ferent locations on

Copy the figures with punched holes and find the axes of symmetry for the following:


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The shape is same, but the other way round!

Play this punching game!

Fold a sheet into two halves Punch a hole two holes about the

symmetric fold.

Fig 14.10The fold is a line (or axis) of symmetry. SThe fold is a line (or axis) of symmetry. SThe fold is a line (or axis) of symmetry tudy about punches at different locations ontudy about punches at different locations ontudy about punches at dif

the folded paper and the corresponding lines of symmetry (Fig 14.10).

EXERCISEEXERCISEE 14.1XERCISE 14.1XERCISE

1. Copy the figures with punched holes and find the axes of symmetry for the following:

(i) (ii)(ii)Fig 14.9

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2. Given the line(s) of symmetry, find the other hole(s):

3. In the following figures, the mirror line (i.e., the line of symmetry) is given as a dotted

line. Complete each figure performing reflection in the dotted (mirror) line. (You might

perhaps place a mirror along the dotted line and look into the mirror for the image).

Are you able to recall the name of the figure you complete?

4. The following figures have more than one line of symmetry. Such figures are said to

have multiple lines of symmetry.

Identify multiple lines of symmetry, if any, in each of the following figures:

(a) (b) (c)

(a) (b) (c) (d) (e) (f)

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2. Given the line(s) of symmetry, find the other hole(s):Given the line(s) of symmetry, find the other hole(s):Given the line(s) of symmetry

3.

4.

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Given the line(s) of symmetry, find the other hole(s):Given the line(s) of symmetry, find the other hole(s):Given the line(s) of symmetry

In the following figures, the mirror line (i.e., the line of symmetry) is given as a dotted

line. Complete each figure performing reflection in the dotted (mirror) line. (You mightline. Complete each figure performing reflection in the dotted (mirror) line. (You mightline. Complete each figure performing reflection in the dotted (mirror) line. (Y

perhaps place a mirror along the dotted line and look into the mirror for the image).

Are you able to recall the name of the figure you complete?

The following figures have more than one line of symmetry. Such figures are said to

have multiple lines of symmetry.have multiple lines of symmetry.have multiple lines of symmetry

Identify multiple lines of symmetry, if any, in each of the following figures:Identify multiple lines of symmetry, if any, in each of the following figures:Identify multiple lines of symmetry

(a) (b) (c)

(a) (b) (c) (d) (e) (f)

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5. Copy the figure given here.

Take any one diagonal as a line of symmetry and shade a few more squares to make

the figure symmetric about a diagonal. Is there more than one way to do that? Will

the figure be symmetric about both the diagonals?

6. Copy the diagram and complete each shape to be symmetric about the mirror line(s):

7. State the number of lines of symmetry for the following figures:

(a) An equilateral triangle (b) An isosceles triangle (c) A scalene triangle

(d) A square (e) A rectangle (f) A rhombus

(g) A parallelogram (h) A quadrilateral (i) A regular hexagon

(j) A circle

8. What letters of the English alphabet have reflectional symmetry (i.e., symmetry related

to mirror reflection) about.

(a) a vertical mirror (b) a horizontal mirror

(c) both horizontal and vertical mirrors

9. Give three examples of shapes with no line of symmetry.

10. What other name can you give to the line of symmetry of

(a) an isosceles triangle? (b) a circle?

14.3 ROTATIONAL SYMMETRY

What do you say when the hands of a clock go round?

You say that they rotate. The hands of a clock rotate in only

one direction, about a fixed point, the centre of the clock-face.

Rotation, like movement of the hands of a clock, is called

a clockwise rotation; otherwise it is said to be anticlockwise.

(a) (b) (c)

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ake any one diagonal as a line of symmetry and shade a few more squares to make

the figure symmetric about a diagonal. Is there more than one way to do that? WillWillW

Copy the diagram and complete each shape to be symmetric about the mirror line(s):

A scalene triangle

A regular hexagon

What letters of the English alphabet have reflectional symmetry (i.e., symmetry related

14.3 ROTATIONAL SOTATIONAL SOTATIONAL YMMETRY

What do you say when the hands of a clock go round?

You say that they rotate. The hands of a clock rotate in onlyYou say that they rotate. The hands of a clock rotate in onlyY

one direction, about a fixed point, the centre of the clock-face.

Rotation, like movement of the hands of a clock, is called

a clockwise rotation; otherwise it is said to be anticlockwise.

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Take any one diagonal as a line of symmetry and shade a few more squares to makeTake any one diagonal as a line of symmetry and shade a few more squares to makeT

the figure symmetric about a diagonal. Is there more than one way to do that?

the figure be symmetric about both the diagonals?

6. Copy the diagram and complete each shape to be symmetric about the mirror line(s):

7. State the number of lines of symmetry for the following figures:

(a) An equilateral triangle (b) An isosceles triangle (c) A scalene triangle

(d) A square (e) A rectangle (f) A rhombus

(g) A parallelogram (h) A quadrilateral (i) A regular hexagon

(j) A circle

8. What letters of the English alphabet have reflectional symmetry (i.e., symmetry related

to mirror reflection) about.

(a) a vertical mirror (b) a horizontal mirror

(c) both horizontal and vertical mirrors

9. Give three examples of shapes with no line of symmetry.Give three examples of shapes with no line of symmetry.Give three examples of shapes with no line of symmetry

10. What other name can you give to the line of symmetry of

(a) an isosceles triangle? (b) a circle?

14.3 ROTATIONAL SOTATIONAL SOTATIONAL YMMETRY

(a) (b) (c)

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What can you say about the rotation of the blades of a ceiling fan? Do they rotateclockwise or anticlockwise? Or do they rotate both ways?

If you spin the wheel of a bicycle, it rotates. It can rotate in either way: both clockwiseand anticlockwise. Give three examples each for (i) a clockwise rotation and (ii) anticlockwiserotation.

When an object rotates, its shape and size do not change. The rotation turns an objectabout a fixed point. This fixed point is the centre of rotation. What is the centre ofrotation of the hands of a clock? Think about it.

The angle of turning during rotation is called the angle of rotation. A fullturn, you know, means a rotation of 360°. What is the degree measure ofthe angle of rotation for (i) a half-turn? (ii) a quarter-turn?

A half-turn means rotation by 180°; a quarter-turn is rotation by 90°.

When it is 12 O’clock, the hands of a clock are together. By 3 O’clock,the minute hand would have made three complete turns; but the hour handwould have made only a quarter-turn. What can you say about their positionsat 6 O’clock?

Have you ever made a paper windmill? The Paper windmill in the picturelooks symmetrical (Fig 14.11); but you do not find any line of symmetry. Nofolding can help you to have coincident halves. However if you rotate it by90° about the fixed point, the windmill will look exactly the same. We say thewindmill has a rotational symmetry.

Fig 14.12In a full turn, there are precisely four positions (on rotation through the angles 90°,

180°, 270° and 360°) when the windmill looks exactly the same. Because of this, we sayit has a rotational symmetry of order 4.

Here is one more example for rotational symmetry.

Consider a square with P as one of its corners (Fig 14.13).

Let us perform quarter-turns about the centre of the square marked .

Fig 14.13

Fig 14.11

A

B

C

D

D

A

B

C

C

D

A

B

B A

C B

D C

A D

90° 90° 90° 90°

P

90°P

P

P90°

P90°90°

(i) (ii) (iii) (iv) (v)

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What can you say about the rotation of the blades of a ceiling fan? Do they rotateclockwise or anticlockwise? Or do they rotate both ways?

If you spin the wheel of a bicycle, it rotates. It can rotate in either way: both clockwiseand anticlockwise. Give three examples each for (i) a clockwise rotation and (ii) anticlockwiserotation.

When an object rotates, its shape and size do not change. The rotation turns an objectabout a fixed point. This fixed point is the centre of rotation. What is the centre ofrotation of the hands of a clock? Think about it.

turn, you the angle of rotation for (i)


the minute hand would have made three complete turns; but the hour handwould at 6

looks symmetrical (Fig 14.11); but you do not find any line of symmetryfolding can help you to have coincident halves. However if you rotate it by90° about the fixed point, the windmill will look exactly the same. windmill has a


Here is one more example for rotational symmetry


Let us perform quarter-turns about the centre of the square marked

Fig 14.13

Fig 14.11

A

P

90°P P

90°

PP90°90°90°

(i) (ii) (iii) (iv) (v)

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rotation of the hands of a clock? Think about it.

The angle of turning during rotation is called the angle of rotation. A fullA fullAturn, you know, means a rotation of 360°. What is the degree measure ofthe angle of rotation for (i) a half-turn? (ii) a quarter-turn?


When it is 12 O’clock, the hands of a clock are together. By 3 O’clock,the minute hand would have made three complete turns; but the hour handwould have made only a quarter-turn. What can you say about their positions

O’clock?

Have you ever made a paper windmill? The Paper windmill in the picturelooks symmetrical (Fig 14.11); but you do not find any line of symmetry. Nofolding can help you to have coincident halves. However if you rotate it by90° about the fixed point, the windmill will look exactly the same. We say theWe say theWwindmill has a rotational symmetry.

Fig 14.12In a full turn, there are precisely four positions (on rotation through the angles 90°,


Here is one more example for rotational symmetry.


Let us perform quarter-turns about the centre of the square marked .

Fig 14.1

B

C

D

D

A

B

C

C

D

AAA

B

B A

C B

DD C

A D

90° 90° 90° 90°

PP PP

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Fig 14.13 (i) is the initial position. Rotation by 90° about the centre leads

to Fig 14.13 (ii). Note the position of P now. Rotate again through 90° and you get

Fig 14.13 (iii). In this way, when you complete four quarter-turns, the square reaches its

original position. It now looks the same as Fig14.13 (i). This can be seen with the help of

the positions taken by P.

Thus a square has a rotational symmetry of order 4 about its centre. Observe that

in this case,

(i) The centre of rotation is the centre of the square.

(ii) The angle of rotation is 90°.

(iii) The direction of rotation is clockwise.

(iv) The order of rotational symmetry is 4.

1. (a) Can you now tell the order of the rotational symmetry for an equilateral triangle?

(Fig 14.14)

Fig 14.14(b) How many positions are there at which the triangle looks exactly the same,

when rotated about its centre by 120°?

2. Which of the following shapes (Fig 14.15) have rotational symmetry about the marked

point.

(i) (ii) (iii) (iv)

Fig 14.15

Draw two identical parallelograms, one-ABCD on a piece of paper and the other

A' B' C' D' on a transparent sheet. Mark the points of intersection of their diagonals,

O and O' respectively (Fig 14.16).

Place the parallelograms such that A' lies on A, B' lies on B and so on. O' then falls

on O.

TRY THESE

120°

120°

120°

R

R R

R

(i) (ii) (iii) (iv)

DO THIS

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Fig 14.13 (i) is the initial position. Rotation by 90° about the centre leads

to Fig 14.13 (ii). Note the position of P now. Rotate again through 90° and you get

Fig 14.13 (iii). In this way, when you complete four quarter-turns, the square reaches its

original position. It now looks the same as Fig14.13 (i). This can be seen with the help of

the positions taken by P.the positions taken by P.the positions taken by P

Thus a square has a rotational symmetry of order 4 about its centre. Observe that

in this case,

Can you now tell the order of the rotational symmetry for an equilateral triangle?

How many positions are there at which the triangle looks exactly the same,

Which of the following shapes (Fig 14.15) have rotational symmetry about the marked

Draw two identical parallelograms, one-ABCD on a piece of paper and the other

A' B' C' D' on a transparent sheet. Mark the points of intersection of their diagonals,

O and O' respectively (Fig 14.16).

Place the parallelograms such that A' lies on A, B' lies on B and so on. O' then falls

on O.

DO THIS

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in this case,

(i) The centre of rotation is the centre of the square.

(ii) The angle of rotation is 90°.

(iii) The direction of rotation is clockwise.

(iv) The order of rotational symmetry is 4.

1. (a) Can you now tell the order of the rotational symmetry for an equilateral triangle?

(Fig 14.14)

Fig 14.14(b) How many positions are there at which the triangle looks exactly the same,

when rotated about its centre by 120°?

2. Which of the following shapes (Fig 14.15) have rotational symmetry about the marked

point.

(i) (ii) (iii) (iv)

Fig 14.15

TTTTRY RY TTTTHESEHESE

120°120°

120°

120°

R

R RR RR R

R

(i) (ii) (iii) (iv)

DDO TTHIS

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Stick a pin into the shapes at the point O.

Now turn the transparent shape in the clockwise direction.

How many times do the shapes coincide in one full round?

What is the order of rotational symmetry?

The point where we have the pin is the centre of rotation. It is the

intersecting point of the diagonals in this case.

Every object has a rotational symmetry of order 1, as it occupies

same position after a rotation of 360° (i.e., one complete revolution).

Such cases have no interest for us.

You have around you many shapes, which possess rotational symmetry

(Fig 14.17).

Fruit Road sign Wheel

(i) (ii) (iii)

Fig 14.17For example, when you slice certain fruits, the cross-sections are shapes with rotational

symmetry. This might surprise you when you notice them [Fig 14.17(i)].

Then there are many road signs that exhibit rotational symmetry. Next time when youwalk along a busy road, try to identify such road signs and find about the order of rotationalsymmetry [Fig 14.17(ii)].

Think of some more examples for rotational symmetry. Discuss in each case:

(i) the centre of rotation (ii) the angle of rotation

(iii) the direction in which the rotation is affected and

(iv) the order of the rotational symmetry.

Give the order of the rotational symmetry of the given figures about the point

marked (Fig 14.17).

(i) (ii) (iii)

Fig 14.16

TRY THESE

Fig 14.18

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Stick a pin into the shapes at the point O.

Now turn the transparent shape in the clockwise direction.

How many times do the shapes coincide in one full round?

What is the order of rotational symmetry?

The point where we have the pin is the centre of rotation. It is the




(Fig 14.17).

symmetry

walk along a busy road, try to identify such road signs and find about the order of rotationalsymmetry [Fig 14.17(ii)].

Think of some more examples for rotational symmetry

marked

(i) (ii) (iii)

Fig 14.18

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Every object has a rotational symmetry of order 1, as it occupies



You have around you many shapes, which possess rotational symmetryYou have around you many shapes, which possess rotational symmetryY

(Fig 14.17).

Fruit Road sign Wheel

(i) (ii) (iii)

Fig 14.17For example, when you slice certain fruits, the cross-sections are shapes with rotational

symmetry. symmetry. symmetry This might surprise you when you notice them [Fig 14.17(i)].

Then there are many road signs that exhibit rotational symmetry. Next time when youwalk along a busy road, try to identify such road signs and find about the order of rotationalsymmetry [Fig 14.17(ii)].

Think of some more examples for rotational symmetry. Discuss in each case:

(i) the centre of rotation (ii) the angle of rotation

(iii) the direction in which the rotation is affected and

(iv) the order of the rotational symmetry.

Give the order of the rotational symmetry of the given figures about the point

marked (Fig 14.17).

Fig 14.16

TTTTRY RY TTTTHESEHESE

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EXERCISE14.2

1. Which of the following figures have rotational symmetry of order more than 1:

(a) (b) (c) (d) (e) (f)

2. Give the order of rotational symmetry for each figure:

(a) (b) (c) (d)

(e) (f) (g) (h)

14.4 LINE SYMMETRY AND ROTATIONAL SYMMETRY

You have been observing many shapes and their symmetries so far. By now you

would have understood that some shapes have only line symmetry, some have only

rotational symmetry and some have both line symmetry and rotational symmetry.

For example, consider the square shape (Fig 14.19).

How many lines of symmetry does it have?

Does it have any rotational symmetry?

If ‘yes’, what is the order of the rotational symmetry?

Think about it.

The circle is the most perfect symmetrical figure, because it can be rotated around

its centre through any angle and at the same time it has unlimited number of lines

of symmetry. Observe any circle pattern. Every line

through the centre (that is every diameter) forms a

line of (reflectional) symmetry and it has rotational

symmetry around the centre for every angle.

Fig 14.19

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EXERCISEEXERCISEE 14.2

1. Which of the following figures have rotational symmetry of order more than 1:

(f)

. By now you

, some have only

rotational symmetry and some have both line symmetry and rotational symmetry.



of symmetry. Observe any circle pattern. Every line

through the centre (that is every diameter) forms a

line of (reflectional) symmetry and it has rotational

symmetry around the centre for every angle.

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(a) (b) (c) (d) (e) (f)

2. Give the order of rotational symmetry for each figure:

(a) (b) (c) (d)

(e) (f) (g) (h)

14.4 LINE14.4 LINE14.4 L SINE SINE YMMETRY AND ROTATIONAL SOTATIONAL SOTATIONAL YMMETRY

You have been observing many shapes and their symmetries so farYou have been observing many shapes and their symmetries so farY . By now youou have been observing many shapes and their symmetries so far. By now youou have been observing many shapes and their symmetries so far

would have understood that some shapes have only line symmetry, some have onlywould have understood that some shapes have only line symmetry, some have onlywould have understood that some shapes have only line symmetry

rotational symmetry and some have both line symmetry and rotational symmetry

For example, consider the square shape (Fig 14.19).

How many lines of symmetry does it have?

Does it have any rotational symmetry?

If ‘yes’, what is the order of the rotational symmetry?

Think about it.



Fig 14.19

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Some of the English alphabets have fascinating symmetrical structures.Which capital

letters have just one line of symmetry (like E)? Which capital letters have a rotational

symmetry of order 2 (like I)?

By attempting to think on such lines, you will be able to fill in the following table:

Alphabet Line Number of Lines of Rotational Order of RotationalLetters Symmetry Symmetry Symmetry Symmetry

Z No 0 Yes 2

S

H Yes Yes

O Yes Yes

E Yes

N Yes

C

EXERCISE 14.3

1. Name any two figures that have both line symmetry and rotational symmetry.

2. Draw, wherever possible, a rough sketch of(i) a triangle with both line and rotational symmetries of order more than 1.(ii) a triangle with only line symmetry and no rotational symmetry of order more

than 1.(iii) a quadrilateral with a rotational symmetry of order more than 1 but not a line

symmetry.(iv) a quadrilateral with line symmetry but not a rotational symmetry of order more than 1.

3. If a figure has two or more lines of symmetry, should it have rotational symmetry of

order more than 1?

4. Fill in the blanks:

Shape Centre of Rotation Order of Rotation Angle of Rotation

Square

Rectangle

Rhombus

Equilateral

Triangle

Regular

Hexagon

Circle

Semi-circle

DO THIS

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Some of the English alphabets have fascinating symmetrical structures.Which capital

letters have just one line of symmetry (like E)? Which capital letters have a rotational

symmetry of order 2 (like I)?

By attempting to think on such lines, you will be able to fill in the following table:

Alphabet Line Number of Lines of Rotational Order of RotationalLetters

1.2.

3.

4. Shape

Square

Rectangle

Rhombus

Equilateral

TriangleTriangleT

Regular

Hexagon

Circle

Semi-circle

DDO TTHIS

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Alphabet Line Number of Lines of Rotational Order of RotationalLetters Symmetry Symmetry Symmetry SymmetrySymmetry Symmetry Symmetry SymmetrySymmetry Symmetry Symmetry SymmetrySymmetry Symmetry Symmetry Symmetry

Z No 0 YesYesY 2

S

H YesYesY YesYesY

O YesYesY YesYesY

E YesYesY

N YesYesY

C

EXERCISEEXERCISEE 14.3XERCISE 14.3XERCISE

Name any two figures that have both line symmetry and rotational symmetryName any two figures that have both line symmetry and rotational symmetryNa .

Draw, wherever possible, a rough sketch of(i) a triangle with both line and rotational symmetries of order more than 1.(ii) a triangle with only line symmetry and no rotational symmetry of order more

than 1.(iii) a quadrilateral with a rotational symmetry of order more than 1 but not a line

symmetry.symmetry.symmetry(iv) a quadrilateral with line symmetry but not a rotational symmetry of order more than 1.If a figure has two or more lines of symmetry, should it have rotational symmetry of

order more than 1?

Fill in the blanks:

Shape Centre of Rotation Order of Rotation Angle of Rotation

Square

Rectangle

Rhombus

Equilateral

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5. Name the quadrilaterals which have both line and rotational symmetry of order more

than 1.

6. After rotating by 60° about a centre, a figure looks exactly the same as its original

position. At what other angles will this happen for the figure?

7. Can we have a rotational symmetry of order more than 1 whose angle of rotation is

(i) 45°? (ii) 17°?

WHAT HAVE WE DISCUSSED?

1. A figure has line symmetry, if there is a line about which the figure may be folded so

that the two parts of the figure will coincide.

2. Regular polygons have equal sides and equal angles. They have multiple (i.e., more

than one) lines of symmetry.

3. Each regular polygon has as many lines of symmetry as it has sides.

Regular Regular Regular Square Equilateral

Polygon hexagon pentagon triangle

Number of lines 6 5 4 3

of symmetry

4. Mirror reflection leads to symmetry, under which the left-right orientation have to be

taken care of.

5. Rotation turns an object about a fixed point.

This fixed point is the centre of rotation.

The angle by which the object rotates is the angle of rotation.

A half-turn means rotation by 180o; a quarter-turn means rotation by 90o. Rotation

may be clockwise or anticlockwise.

6. If, after a rotation, an object looks exactly the same, we say that it has a rotationalsymmetry.

7. In a complete turn (of 360o), the number of times an object looks exactly the same is

called the order of rotational symmetry. The order of symmetry of a square, for

example, is 4 while, for an equilateral triangle, it is 3.

8. Some shapes have only one line of symmetry, like the letter E; some have only rotational

symmetry, like the letter S; and some have both symmetries like the letter H.

The study of symmetry is important because of its frequent use in day-to-day life and

more because of the beautiful designs it can provide us.

2019-20

5. Name the quadrilaterals which have both line and rotational symmetry of order more

than 1.

6. After rotating by 60° about a centre, a figure looks exactly the same as its original

position. At what other angles will this happen for the figure?

7. Can we have a rotational symmetry of order more than 1 whose angle of rotation is

(i) 45°? (ii) 17°?

, if there is a line about which the figure may be folded so

Regular polygons have equal sides and equal angles. They have multiple (i.e., more

Equilateral

triangle

3

Mirror reflection leads to symmetry, under which the left-right orientation have to be

. Rotation

rotational

), the number of times an object looks exactly the same is

The order of symmetry of a square, for

Some shapes have only one line of symmetry, like the letter E; some have only rotational


more because of the beautiful designs it can provide us.

2019-20

WHAT HAVE WE DISCUSSED?

1. A figure has A figure has A line symmetryline symmetryline symmetr , if there is a line about which the figure may be folded so

that the two parts of the figure will coincide.

2. Regular polygons have equal sides and equal angles. They have multiple (i.e., more

than one) lines of symmetry.

3. Each regular polygon has as many lines of symmetry as it has sides.

Regular Regular Regular Square Equilateral

Polygon hexagon pentagon triangle

Number of lines 6 5 4 3

of symmetry

4. Mirror reflection leads to symmetry, under which the left-right orientation have to be

taken care of.

5. Rotation turns an object about a fixed point.

This fixed point is the centre of rotation.

The angle by which the object rotates is the angle of rotation.

A half-turn means rotation by 180o; a quarter-turn means rotation by 90o. Rotation

may be clockwise or anticlockwise.

6. If, after a rotation, an object looks exactly the same, we say that it has a rotationalsymmetrysymmetrysymmetr .

7. In a complete turn (of 360o), the number of times an object looks exactly the same is

called the order of rorder of rorder otational symmetry. The order of symmetry of a square, for

example, is 4 while, for an equilateral triangle, it is 3.

8. Some shapes have only one line of symmetry, like the letter E; some have only rotational

symmetry, like the letter S; and some have both symmetries like the letter H.symmetry, like the letter S; and some have both symmetries like the letter H.symmetry


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