# NCERT Solutions For Class 10 Maths Chapter 12 Exercise 12.1

## Chapter 12 Ex.12.1 Question 1

The radii of two circles are $$19\, \rm{cm}$$ and $$9\,\rm{cm}$$ respectively. Find the radius of the circle which has circumference equal to the sum of the circumferences of the two circles.

### Solution

What is known?

Radii of two circles.

What is unknown?

Radius of $$3^\rm{rd}$$ circle.

Reasoning:

Using the formula of circumference of circle $${C = 2}\pi r$$ we find the radius of the circle.

Steps:

Radius $$({r_1})$$of $$1^ \rm{st}$$ circle $$= 19 \,\rm{cm}$$

Radius $$({r_2})$$ or $$2^\rm{nd}$$ circle $$=9\,\rm{cm}$$

Let the radius of $$3^ \rm{rd}$$ circle be $$r.$$

Circumference of $$1^\rm{st}$$ circle

$$= 2 \pi{{\text{r}}_{\text{1}}}{\text{ = 2 }}\pi (19) = 38 \pi$$

Circumference of$$2^\rm{ nd }$$ circle

$$= 2 \pi{{\text{r}}_{\text{2}}}{\text{ = 2 }}\pi (9) = 18 \pi$$

Circumference of $$3^\rm{rd}$$circle $$=2\pi r$$

Given that,

Circumference of $$3^\rm{rd}$$ $$\rm{}circle$$ $$=$$ Circumference of $$1^\rm{st }$$ $$\rm{}circle$$ $$+$$Circumference of $$2^\text{nd}$$$$\rm{}circle.$$

\begin{align} 2 \pi r &=38 \pi+18 \pi \\ &=56 \pi \\ r &=\frac{56 \pi}{2 \pi} \\ &=28 \end{align}

Therefore, the radius of the circle which has circumference equal to the sum of the circumference of the given two circles is $$28\, \rm{cm.}$$

## Chapter 12 Ex.12.1 Question 2

The radii of two circles are $$8\,\rm{cm}$$ and $$6\,\rm{cm}$$ respectively. Find the radius of the circle having area equal to the sum of the areas of the two circles.

### Solution

What is known?

Radii of two circles.

What is unknown?

Radius of $$3^\rm{rd}$$ circle.

Reasoning:

Using the formula of area of circle $$A = \pi {r^2}$$ we find the radius of the circle.

Steps:

Radius of $$(r_1)$$ $$1^\rm{st}$$ circle $$= 8\,\rm{cm}$$

Radius of $$(r_2)$$$$2^\rm{nd}$$ circle $$= 6\,\rm{cm}$$

Let the radius of $$3^\rm{rd}$$ circle $$=r.$$

Area of

$$1^\rm{st}$$circle $$=\pi \rm{r}_{1}^{2}= \pi (8)^2= 64\pi$$

Area of

$$2^\rm{nd}$$ circle $$=\pi \rm{r}_{2}^{2}= \pi (6)^2= 36\pi$$

Given that,

Area of $$3^\rm{rd}$$ circle $$=$$ Area of $$1^\rm{st}$$  circle $$+$$ Area of $$2^\rm{nd}$$ circle

\begin{align}{\pi{{{r}}^{{2}}}}& = {\pi {{r}}_{{1}}^{{2}}\,{{ + }}\,\pi {{r}}_{{2}}^{{2}}}\\{\pi {{{r}}^{{2}}}} &= {64\pi \,{{ + }}\,36\pi }\\{\pi{{{r}}^{{2}}}} &= {{100\pi }}\\{\,\,{{{r}}^{{2}}}} &={{{100}}}\\{\,\,{{r}}} &= \,\pm \,10\end{align}

However, the radius cannot be negative. Therefore, the radius of the circle having area equal to the sum of the areas of the two circles is $$10\,\rm{cm.}$$

## Chapter 12 Ex.12.1 Question 3

Given figure depicts an archery target marked with its five scoring areas from the centre outwards as Gold, Red, Blue, Black and White. The diameter of the region representing Gold score is $$21 \,\rm{cm}$$ and each of the other bands is $$10.5 \,\rm{cm}$$ wide. Find the area of each of the five scoring regions.

[Use $$\pi= \,\frac{22}{7}$$]

### Solution

What is known?

Diameter of the gold region and width of the other regions.

What is unknown?

Area of each scoring region.

Reasoning:

Area of the region between $$2$$ concentric circles is given by \begin{align}\pi {\text{r}}_2^2 - \pi {\text{r}}_1^2\end{align}.

Steps:

Radius$$({r_1})$$ of gold region (i.e., $$1^\rm{st}$$ circle)$$= \frac{{21}}{2} = 10.5\,{\text{cm}}$$

Given that each circle is $$10.5\,\rm{cm}$$ wider than the previous circle.

Therefore,

Radius $$(r_2)$$ of $$2^\rm{nd}$$ circle

\begin{align}&= 10.5 + 10.5\\&=21 \,\rm{cm}\end{align}

Radius $$({r_3})$$ of $$3^\rm{rd}$$circle

\begin{align}&= 21 + 10.5\\ &= 31.5\,{\text{cm}}\end{align}

Radius $$(r_4)$$ of $$4^\rm{th}$$ circle

\begin{align}&= 31.5 + 10.5\\ &= 42\,{\text{cm}}\end{align}

Radius $$(r_5)$$ of $$5^\rm{th}$$ circle

\begin{align}&= 42 + 10.5\\ &= 52.5\,\,{\text{cm}} \end{align}

Area of gold region$$=$$  Area of $$1^\rm{st}$$ circle $$= \pi {r}_1^2 = \pi {(10.5)^2} = 346.5\;\rm{cm^2}$$

Area of red region $$=$$Area of $$2^\text{nd }$$circle $$-$$ Area of $$1^\rm{ st }$$circle

\begin{align}& = \pi {\text{r}}_2^2 - \pi {\text{r}}_1^2\\& = \pi {{(21)}^2} - {{(10.5)}^2}\\& = 441\pi - 110.25\pi = 330.75\pi \\& = 1039.5\,{\text{c}}{{\text{m}}^2}\end{align}

Area of blue region $$=$$ Area of $$3^\text{rd}$$ circle $$-$$ Area of $$2^\rm{nd}$$circle

\begin{align}&= \pi _{13}^2 - \pi {\text{r}}_1^2\\& = \pi {{(31.5)}^2} - \pi {{(21)}^2}\\&= 992.25\pi - 441\pi = 551.25\pi \\&= 1732.5\,{\text{c}}{{\text{m}}^2}\end{align}

Area of black region$$=$$ Area of $$4^\rm{th}$$ circle $$-$$Area of $$3^\rm{rd}$$circle

\begin{align}& = \pi r_4^2 - \pi r_3^2\\& = \pi {{(42)}^2} - \pi {{(31.5)}^2}\\&= 1764\pi - 992.25\pi \\&= 771.75\pi \\ &= 2425.5\,{\text{c}}{{\text{m}}^2}\end{align}

Area of white region $$=$$ Area of $$5^\rm{th}$$ circle $$-$$ Area of $$4^\rm{th}$$circle

\begin{align}&= \pi {\text{r}}_5^2 - \pi \pi _4^2\\&= \pi {{(52.5)}^2} - \pi {{(42)}^2}\\&= 2756.25\pi - 1764\pi \\&= 992.25\pi \\ &= 3118.5\,{\text{c}}{{\text{m}}^2}\end{align}

Therefore,areas of gold, red, blue, black, and white regions are $$346.5\, \rm{cm^2},$$$$1039.5 \,\rm{cm^2},$$ $$1732.5 \,\rm{cm^2},$$ $$2425.5\,\rm{cm^2},$$and$$3118.5 \,\rm{cm^2}$$ respectively.

## Chapter 12 Ex.12.1 Question 4

The wheels of a car are of diameter $$80\, \rm{cm}$$ each. How many complete revolutions does each wheel make in $$10$$ minutes when the car is traveling at a speed of $$66\, \rm{km}$$ per hour?

### Solution

What is known?

Diameter of the wheel of the car and the speed of the car.

What is unknown?

Revolutions made by each wheel.

Reasoning:

Distance travelled by the wheel in one revolution is nothing but the circumference of the wheel itself.

Steps:

Diameter of the wheel of the car $$= 80\,\rm{cm}$$

Radius $$(r)$$ of the wheel of the car $$= 40\,\rm{cm}$$

Distance travelled in $$1$$ revolution $$=$$ Circumference of wheel

Circumference of wheel

\begin{align}&= 2\pi \,{ r}\\& = 2\pi \left( {{\text{40}}} \right)\\&= 80\pi\, \rm{cm}\end{align}

Speed of car$$= 66\, \text{km/hour}$$

\begin{align}&= \frac{{66 \times {\text{ }}100000}}{{60}}\,{\text{cm/}}\,{\text{min}}\\&= 110000 {\text{ cm/min}}\end{align}

Distance travelled by the car in $$10$$ minutes

\begin{align}&= {\text{ }}110000{\text{ }} \times {\text{ }}10{\text{ }}\\&= {\text{ }}1100000{\text{ cm}}\end{align}

Let the number of revolutions of the wheel of the car be $$n$$

$$\rm{n} \times$$Distance travelled in$$1$$ revolution $$=$$Distance travelled in $$10$$ minutes

\begin{align}\\\rm{n} \times 80\pi &= 1100000\\{\text{n}} &= \frac{{1100000 \times 7}}{{80 \times 22}}\\ &= \frac{{35000}}{8}\\&= 4375\end{align}

Therefore, each wheel of the car will make $$4375$$ revolutions.

## Chapter 12 Ex.12.1 Question 5

Tick the correct answer in the following and justify your choice: If the perimeter and the area of a circle are numerically equal, then the radius of the circle is

(A) $$2$$ units

(B) $$\pi$$ units

(C) $$4$$ units

(D) $$7$$ units

### Solution

What is known?

Perimeter and area of the circle are numerically equal.

What is unknown?

Reasoning:

Given that Perimeter and area of the circle are numerically equal. We get $$2\pi \rm{r}= \pi \rm{r^2}.$$

Using this relation we find the radius.

Steps:

Let the radius of the circle $$= r.$$

Circumference of circle $$= 2\pi r$$

Area of circle $$= \pi \rm{r^2}$$

Given that, the circumference of the circle and the area of the circle are equal.

This implies \begin{align}2\pi \rm{r} &= \pi \rm{r^2}\\2 &= \rm{r}\end{align}

Therefore, the radius of the circle is $$2$$ units.

Hence, the correct answer is $$\rm{A.}$$

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Ncert Class 10 Exercise 12.1
Ncert Solutions For Class 10 Maths Chapter 12 Exercise 12.1
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