Understanding Elementary Shapes ( Exercise 5.1 )

Ex 5.1 Question 1.

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What is the disadvantage in comparing line segments by mere observation?
Solution:

Comparing the line segment by mere observation may not be accurate.

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Ex 5.1 Question 2.

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Why is it better to use a divider than a ruler, while measuring the length of a line segment?
Solution:

It is better to use a divider than a ruler while measuring the length of a line segment because if we use a ruler while measuring the length of a line segment we may have the following errors:

(i) The thickness of the ruler
(ii) Angular viewing

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Ex 5.1 Question 3.

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Draw any line segment, say . Take any point C lying in between A and B. Measure the lengths of AB, BC and AC. Is AB = AC + CB?
[Note: If A, B, C are any three points on a line such AC + CB = AB, then we can be sure that C lies between A and B]
Solution:

AB is a line segment of length 7 cm

C is a point between A and B

Such that AC = 3 cm and CB = 4 cm.

AC = 3 cm, CB = 4 cm.
∴ AC + CB = 3 cm + 4 cm = 7 cm.
But, AB = 7 cm.
So, AB = AC + CB.

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Ex 5.1 Question 4.

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If A, B, C are three points on a line such that AB = 5 cm, BC = 3 cm and AC = 8 cm, which one of them lies between the other two?
Solution:

AB = 5 cm; BC = 3 cm
∴ AB + BC = 5 + 3 = 8 cm
But, AC = 8 cm
Hence, B lies between A and C.

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Ex 5.1 Question 5.

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Verify, whether D is the mid point of  .

Solution:

AG = 7 cm – 1 cm = 6 cm
AD = 4 cm – 1 cm = 3 cm
and DG = 7 cm – 4 cm = 3 cm
∴ AG = AD + DG.
Hence, D is the mid point of .

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Ex 5.1 Question 6.

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If B is the mid point of  and C is the mid point of  , where A, B, C, D lie on a straight line, say why AB = CD?
Solution:

 B is the midpoint of .

∴ AB = BC …..…(i)
C is the mid-point of .

BC = CD ………..(ii)
Therefore from Eq.(i) and (ii)
AB = CD

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Ex 5.1 Question 7.

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Draw five triangles and measure their sides. Check in each case, if the sum of the length of any two sides is always less than the third side.
Solution:

Case I. In ∆ABC

AB = 2.5 cm

BC = 4.8 cm
and AC = 5.2 cm
AB + BC = 2.5 cm + 4.8 cm
= 7.3 cm
Since, 7.3 > 5.2
So, AB + BC > AC

Hence, sum of any two sides of a triangle is greater than the third side.

Case II. In ∆PQR,

PQ = 2 cm

QR = 2.5 cm

and PR = 3.5 cm

PQ + QR = 2 cm + 2.5 cm = 4.5 cm

Since, 4.5 > 3.5

So, PQ + QR > PR

Hence, sum of any two sides of a triangle is greater than the third side.

Case III. In ∆XYZ,

XY = 5 cm

YZ = 3 cm

and ZX = 6.8 cm

XY + YZ = 5 cm + 3 cm

= 8 cm

Since, 8 > 6.8

So, XY + YZ > ZX

Hence, the sum of any two sides of a triangle is greater than the third side.

Case IV. In ∆MNS,

MN = 2.7 cm

NS = 4 cm

MS = 4.7 cm

and MN + NS = 2.7 cm + 4 cm = 6.7 cm

Since, 6.7 >4.7

So, MN + NS > MS

Hence, the sum of any two sides of a triangle is greater than the third side.

Case V. In ∆KLM,

KL = 3.5 cm

LM = 3.5 cm

KM = 3.5 cm

and KL + LM = 3.5 cm + 3.5 cm = 7 cm

7 cm > 3.5 cm

Solution:

(i) For one-fourth revolution, we have

So, KL + LM > KM

Hence, the sum of any two sides of a triangle is greater than the third side.

Hence, we conclude that the sum of any two sides of a triangle is never less than the third