Answer :

The given inequality is $24 x<100$.

$24 x<100$

$\Rightarrow \frac{24 x}{24}<\frac{100}{24} \quad$ [Dividing both sides by same positive number]

$\Rightarrow x<\frac{25}{6}$

(i) It is evident that $1,2,3$, and 4 are the only natural numbers less than $\frac{25}{6}$.

Thus, when $x$ is a natural number, the solutions of the given inequality are $1,2,3$, and 4 .

Hence, in this case, the solution set is $ \{1,2,3,4\} $.

(ii) The integers less than $\frac{25}{6}$ are …-3, -2, -1, $0,1,2,3,4$.

Thus, when $x$ is an integer, the solutions of the given inequality are

…-3, -2, -1, 0, 1, 2, 3, 4.

Hence, in this case, the solution set is $ \{\ldots - 3 , - 2 , -1, 0,1,2,3,4\} $.

Answer :

The given inequality is - $12 x>30$. $-12 x>30$

$\Rightarrow \frac{-12 x}{-12}<\frac{30}{-12} \quad$ [Dividing both sides by same negative number]

$\Rightarrow x<-\frac{5}{2}$

(i) There is no natural number less than

$ (-\frac{5}{2}) $

Thus, when xis a natural number, there is no solution of the given inequality.

(ii) The integers less than $(-\frac{5}{2})$ are …, -5, -4, -3.

Thus, when xis an integer, the solutions of the given inequality are

…, -5, -4, -3.

Hence, in this case, the solution set is $ \{{-5, -4, -3} \}$.

Answer :

The given inequality is $5 x - 3<7$.

$5 x-3<7$

$\Rightarrow 5 x-3+3<7+3$

$\Rightarrow 5 x<10$

$\Rightarrow \frac{5 x}{5}<\frac{10}{5}$

$\Rightarrow x<2$

(i) The integers less than 2are …, -4, -3, -2, -1, 0,1 .

Thus, when xis an integer, the solutions of the given inequality are

…, -4, -3, -2, -1, 0, 1.

Hence, in this case, the solution set is $\{-4, - 3 , - 2, - 1,0,1\}$.

(ii) When $x$ is a real number, the solutions of the given inequality are given by $x<2$, that is, all real numbers $x$ which are less than 2.

Thus, the solution set of the given inequality is $x \in(- \infty, 2)$.

Answer :

The given inequality is $3 x+8>2$.

$3 x+8>2$

$\Rightarrow 3 x+8-8>2-8$

$\Rightarrow 3 x>-6$

$\Rightarrow \frac{3 x}{3}>\frac{-6}{3}$

$\Rightarrow x>-2$

(i) The integers greater than -2are -1, 0, 1, 2, ..

Thus, when xis an integer, the solutions of the given inequality are

-1, $0,1,2 \ldots$

Hence, in this case, the solution set is $\{- 1,0,1,2, \ldots\}$.

(ii) When xis a real number, the solutions of the given inequality are all the real numbers, which are greater than - 2 .

Thus, in this case, the solution set is (- $2, \infty$ ).

Solve the inequalities in Exercises 5 to 16 for real $x$.

Answer :

$4 x+3<5 x+7$

$\Rightarrow 4 x+3-7<5 x+7-7$

$\Rightarrow 4 x-4<5 x$

$\Rightarrow 4 x-4-4 x<5 x-4 x$

$\Rightarrow-4<x$

Thus, all real numbers $x$, which are greater than -4 , are the solutions of the given inequality.

Hence, the solution set of the given inequality is $(-4, \infty)$.

Answer :

$ \Rightarrow 3 x-7+7>5 x - 1+7$

$\Rightarrow 3 x>5 x+6$

$\Rightarrow 3 x - 5 x>5 x+6$- $5 x$

$\Rightarrow - 2 x>6$

$\Rightarrow \frac{-2 x}{-2}<\frac{6}{-2}$

$\Rightarrow x<-3$

Thus, all real numbers $x$, which are less than - 3 , are the solutions of the given inequality.

Hence, the solution set of the given inequality is (-$\infty$, - 3 ).

Answer :

$3(x-1) \leq 2(x-3)$

$\Rightarrow 3 x-3 \leq 2 x-6$

$\Rightarrow 3 x-3+3 \leq 2 x-6+3$

$\Rightarrow 3 x \leq 2 x-3$

$\Rightarrow 3 x-2 x \leq 2 x-3$ - $2 x$

$\Rightarrow x \leq -3$

Thus, all real numbers $x$, which are less than or equal to -3 , are the solutions of the given inequality.

Hence, the solution set of the given inequality is $(-\infty,-3]$.

Answer :

$3(2-x) \geq 2(1-x)$

$\Rightarrow 6-3 x \geq 2-2 x$

$\Rightarrow 6-3 x+2 x \geq 2-2 x+2 x$

$\Rightarrow 6-x \geq 2$

$ \begin{aligned} & \Rightarrow 6-x-6 \geq 2-6 \\ & \Rightarrow-x \geq-4 \\ & \Rightarrow x \leq 4 \end{aligned} $

Thus, all real numbers $x$, which are less than or equal to 4 , are the solutions of the given inequality.

Hence, the solution set of the given inequality is $(-\infty,4]$.

Answer :

$ \begin{aligned} & x+\frac{x}{2}+\frac{x}{3}<11 \\ & \Rightarrow x(1+\frac{1}{2}+\frac{1}{3})<11 \\ & \Rightarrow x(\frac{6+3+2}{6})<11 \\ & \Rightarrow \frac{11 x}{6}<11 \\ & \Rightarrow \frac{11 x}{6 \times 11}<\frac{11}{11} \\ & \Rightarrow \frac{x}{6}<1 \\ & \Rightarrow x<6 \end{aligned} $

Thus, all real numbers $x$, which are less than 6 , are the solutions of the given inequality.

Hence, the solution set of the given inequality is (-$\infty$, 6).

Answer :

$\frac{x}{3}>\frac{x}{2}+1$

$\Rightarrow \frac{x}{3}-\frac{x}{2}>1$

$\Rightarrow \frac{2 x-3 x}{6}>1$

$\Rightarrow-\frac{x}{6}>1$

$\Rightarrow-x>6$

$\Rightarrow x<-6$

Thus, all real numbers $x$, which are less than - 6 , are the solutions of the given inequality.

Hence, the solution set of the given inequality is (-$\infty$, -6).

Answer :

$\frac{3(x-2)}{5} \leq \frac{5(2-x)}{3}$

$\Rightarrow 9(x-2) \leq 25(2-x)$

$\Rightarrow 9 x-18 \leq 50-25 x$

$\Rightarrow 9 x-18+25 x \leq 50$

$\Rightarrow 34 x-18 \leq 50$

$\Rightarrow 34 x \leq 50+18$

$\Rightarrow 34 x \leq 68$

$\Rightarrow \frac{34 x}{34} \leq \frac{68}{34}$

$\Rightarrow x \leq 2$

Thus, all real numbers $x$, which are less than or equal to 2 , are the solutions of the given inequality.

Hence, the solution set of the given inequality is [ - $\infty, 2 $].

Answer :

$\frac{1}{2}(\frac{3 x}{5}+4) \geq \frac{1}{3}(x-6)$

$\Rightarrow 3(\frac{3 x}{5}+4) \geq 2(x-6)$

$\Rightarrow \frac{9 x}{5}+12 \geq 2 x-12$

$\Rightarrow 12+12 \geq 2 x-\frac{9 x}{5}$

$\Rightarrow 24 \geq \frac{10 x-9 x}{5}$

$\Rightarrow 24 \geq \frac{x}{5}$

$\Rightarrow 120 \geq x$

Thus, all real numbers $x$, which are less than or equal to 120 , are the solutions of the given inequality. Hence, the solution set of the given inequality is (- $\infty, 120$ ).

Answer :

$ \begin{aligned} & 2(2 x+3)-10<6(x-2) \\ & \Rightarrow 4 x+6-10<6 x-12 \\ & \Rightarrow 4 x-4<6 x-12 \\ & \Rightarrow-4+12<6 x-4 x \\ & \Rightarrow 8<2 x \\ & \Rightarrow 4<x \end{aligned} $

Thus, all real numbers $x$, which are greater than or equal to 4 , are the solutions of the given inequality. Hence, the solution set of the given inequality is $(4, \infty)$.

Answer :

$37-(3 x+5) \geq 9 x-8(x-3)$

$\Rightarrow 37-3 x-5 \geq 9 x-8 x+24$

$\Rightarrow 32-3 x \geq x+24$

$\Rightarrow 32-24 \geq x+3 x$

$\Rightarrow 8 \geq 4 x$

$\Rightarrow 2 \geq x$

Thus, all real numbers $x$, which are less than or equal to 2 , are the solutions of the given inequality.

Hence, the solution set of the given inequality is $(- \infty, 2]$.

Answer :

$\frac{x}{4}<\frac{(5 x-2)}{3}-\frac{(7 x-3)}{5}$

$\Rightarrow \frac{x}{4}<\frac{5(5 x-2)-3(7 x-3)}{15}$

$\Rightarrow \frac{x}{4}<\frac{25 x-10-21 x+9}{15}$

$\Rightarrow \frac{x}{4}<\frac{4 x-1}{15}$

$\Rightarrow 15 x<4(4 x-1)$

$\Rightarrow 15 x<16 x-4$

$\Rightarrow 4<16 x-15 x$

$\Rightarrow 4<x$

Thus, all real numbers $x$, which are greater than 4 , are the solutions of the given inequality.

Hence, the solution set of the given inequality is $(4, \infty)$.

Answer :

$\frac{(2 x-1)}{3} \geq \frac{(3 x-2)}{4}-\frac{(2-x)}{5}$

$\Rightarrow \frac{(2 x-1)}{3} \geq \frac{5(3 x-2)-4(2-x)}{20}$

$\Rightarrow \frac{(2 x-1)}{3} \geq \frac{15 x-10-8+4 x}{20}$

$\Rightarrow \frac{(2 x-1)}{3} \geq \frac{19 x-18}{20}$

$\Rightarrow 20(2 x-1) \geq 3(19 x-18)$

$\Rightarrow 40 x-20 \geq 57 x-54$

$\Rightarrow-20+54 \geq 57 x-40 x$

$\Rightarrow 34 \geq 17 x$

$\Rightarrow 2 \geq x$

Thus, all real numbers $x$, which are less than or equal to 2 , are the solutions of the given inequality.

Hence, the solution set of the given inequality is (- $\infty, 2$).

Solve the inequalities in Exercises 17 to 20 and show the graph of the solution in each case on number line

Answer :

$3 x-2<2 x+1$

$\Rightarrow 3 x-2 x<1+2$

$\Rightarrow x<3$

The graphical representation of the solutions of the given inequality is as follows.

Answer :

$3(1-x)<2(x+4)$

$\Rightarrow 3-3 x<2 x+8$

$\Rightarrow 3-8<2 x+3 x$

$\Rightarrow-5<5 x$

$\Rightarrow \frac{-5}{5}<\frac{5 x}{5}$

$\Rightarrow-1<x$

The graphical representation of the solutions of the given inequality is as follows.

Answer :

$5 x-3 \geq 3 x-5$

$\Rightarrow 5 x-3 x \geq-5+3$

$\Rightarrow 2 x \geq-2$

$\Rightarrow \frac{2 x}{2} \geq \frac{-2}{2}$

$\Rightarrow x \geq-1$

The graphical representation of the solutions of the given inequality is as follows.

Answer :

$\frac{x}{2} \geq \frac{(5 x-2)}{3}-\frac{(7 x-3)}{5}$

$\Rightarrow \frac{x}{2} \geq \frac{5(5 x-2)-3(7 x-3)}{15}$

$\Rightarrow \frac{x}{2} \geq \frac{25 x-10-21 x+9}{15}$

$\Rightarrow \frac{x}{2} \geq \frac{4 x-1}{15}$

$\Rightarrow 15 x \geq 2(4 x-1)$

$\Rightarrow 15 x \geq 8 x-2$

$\Rightarrow 15 x-8 x \geq 8 x-2-8 x$

$\Rightarrow 7 x \geq-2$

$\Rightarrow x \geq-\frac{2}{7}$

The graphical representation of the solutions of the given inequality is as follows.

Answer :

Let $x$ be the marks obtained by Ravi in the third unit test.

Since the student should have an average of at least 60 marks,

$\frac{70+75+x}{3} \geq 60$

$\Rightarrow 145+x \geq 180$

$\Rightarrow x \geq 180-145$

$\Rightarrow x \geq 35$

Thus, the student must obtain a minimum of 35 marks to have an average of at least 60 marks.

Answer :

Let $x$ be the marks obtained by Sunita in the fifth examination.

In order to receive grade ‘A’ in the course, she must obtain an average of 90 marks or more in five examinations.

Therefore,

$ \begin{aligned} & \frac{87+92+94+95+x}{5} \geq 90 \\ & \Rightarrow \frac{368+x}{5} \geq 90 \\ & \Rightarrow 368+x \geq 450 \\ & \Rightarrow x \geq 450-368 \\ & \Rightarrow x \geq 82 \end{aligned} $

Thus, Sunita must obtain greater than or equal to 82 marks in the fifth examination.

Answer :

Let $x$ be the smaller of the two consecutive odd positive integers. Then, the other integer is $x+2$.

Since both the integers are smaller than 10 ,

$x+2<10$

$\Rightarrow x<10$ - 2

$\Rightarrow x<8 \ldots$ (i)

Also, the sum of the two integers is more than 11 .

$\therefore x+(x+2)>11$

$\Rightarrow 2 x+2>11$

$\Rightarrow 2 x>11$ - 2

$\Rightarrow 2 x>9$

$\Rightarrow x>\frac{9}{2}$

$\Rightarrow x>4.5$

From (i) and (ii), we obtain

Since $x$ is an odd number, $x$ can take the values, 5 and 7 .

Thus, the required possible pairs are $(5,7)$ and $(7,9)$.

Answer :

Let the length of the shortest side of the triangle be $x cm$.

Then, length of the longest side $=3 x cm$

Length of the third side $=(3 x - 2) cm$

Since the perimeter of the triangle is at least $61 cm$,

$x cm+3 x cm+(3 x-2) cm \geq 61 cm$

$\Rightarrow 7 x-2 \geq 61$

$\Rightarrow 7 x \geq 61+2$

$\Rightarrow 7 x \geq 63$

$\Rightarrow \frac{7 x}{7} \geq \frac{63}{7}$

$\Rightarrow x \geq 9$

Thus, the minimum length of the shortest side is $9 cm$.

Answer :

Let the length of the shortest piece be $x cm$. Then, length of the second piece and the third piece are $(x+3) cm$ and $2 x cm$ respectively.

Since the three lengths are to be cut from a single piece of board of length $91 cm$,

$x cm+(x+3) cm+2 x cm \leq 91 cm$

$\Rightarrow 4 x+3 \leq 91$ $\Rightarrow 4 x \leq 91$ - 3

$\Rightarrow 4 x \leq 88$

$\Rightarrow \frac{4 x}{4} \leq \frac{88}{4}$

$\Rightarrow x \leq 22$

Also, the third piece is at least $5 cm$ longer than the second piece.

$\therefore 2 x \geq(x+3)+5$

$\Rightarrow 2 x \geq x+8$

$\Rightarrow x \geq 8 \ldots(2)$

From (1) and (2), we obtain

$8 \leq x \leq 22$

Thus, the possible length of the shortest board is greater than or equal to $8 cm$ but less than or equal to $22 cm$.

Answer :

$2 \leq 3 x-4 \leq 5$

$\Rightarrow 2+4 \leq 3 x-4+4 \leq 5+4$

$\Rightarrow 6 \leq 3 x \leq $ 9

$\Rightarrow 2 \leq x \leq 3$

Thus, all the real numbers, $x$, which are greater than or equal to 2 but less than or equal to 3 , are the solutions of the given inequality. The solution set for the given inequalityis $[2,3]$.

Answer :

$6 \leq A a-3(2 x-4)<12$

$\Rightarrow 2 \leq -(2 x-4) < 4$

$\Rightarrow-2 \geq 2 x-4>-4$

$\Rightarrow 4$ - $2 \geq 2 x>4$ - 4

$\Rightarrow 2 \geq 2 x>0$

$\Rightarrow 1 > x>0$

Thus, the solution set for the given inequalityis $(0,1]$.

Answer :

$-3 \leq 4-\frac{7 x}{2} \leq 18$

$\Rightarrow-3-4 \leq-\frac{7 x}{2} \leq 18-4$

$\Rightarrow-7 \leq-\frac{7 x}{2} \leq 14$

$\Rightarrow 7 \geq \frac{7 x}{2} \geq-14$

$\Rightarrow 1 \geq \frac{x}{2} \geq-2$

$\Rightarrow 2 \geq x \geq-4$

Thus, the solution set for the given inequalityis [-4, 2].

Answer :

$-15<\frac{3(x-2)}{5} \leq 0$

$\Rightarrow$ - $75<3(x - 2) \leq 0$

$\Rightarrow$ - $25<x - ~ 2 \leq 0$ $\Rightarrow - 25+2<x \leq 2$

$\Rightarrow -23<x \leq 2$

Thus, the solution set for the given inequalityis (-23, 2).

Answer :

$-12<4-\frac{3 x}{-5} \leq 2$

$\Rightarrow-12-4<\frac{-3 x}{-5} \leq 2-4$

$\Rightarrow-16<\frac{3 x}{5} \leq-2$

$\Rightarrow-80<3 x \leq-10$

$\Rightarrow \frac{-80}{3}<x \leq \frac{-10}{3}$

Thus, the solution set for the given inequalityis $(\frac{-80}{3}, \frac{-10}{3}]$.

Answer :

$7 \leq \frac{(3 x+11)}{2} \leq 11$

$\Rightarrow 14 \leq 3 x+11 \leq 22$

$\Rightarrow 14-11 \leq 3 x \leq 22-11$

$\Rightarrow 3 \leq 3 x \leq 11$

$\Rightarrow 1 \leq x \leq \frac{11}{3}$

Thus, the solution set for the given inequalityis $[1, \frac{11}{3}]$.

Solve the inequalities in Exercises 7 to 10 and represent the solution graphically on number line.

Answer :

$5 x+1>-24$

$\Rightarrow 5 x>-25$

$\Rightarrow x>-5$

$5 x-1<24$

$\Rightarrow 5 x<25$

$\Rightarrow x<5$

From (1) and (2), it can be concluded that the solution set for the given system of inequalities is $(-5,5)$. The solution of the given system of inequalities can be represented on number line as

Answer :

$2(x-1)<x+5$

$\Rightarrow 2 x-2<x+5$

$\Rightarrow 2 x-x<5+2$

$\Rightarrow x<7 \ldots$ (1)

$3(x+2)>2-x$

$\Rightarrow 3 x+6>2-x$

$\Rightarrow 3 x+x>2-6$

$\Rightarrow 4 x>-4$

$\Rightarrow x>-1 \ldots(2)$

From (1) and (2), it can be concluded that the solution set for the given system of inequalities is (-1, 7). The solution of the given system of inequalities can be represented on number line as

Answer :

$3 x$ - $7>2 (x $ - 6 $ ) $

$\Rightarrow 3 x$ - $7>2 x$ - 12

$\Rightarrow 3 x$ - $2 x>$ - $12+7$

$\Rightarrow x>$- 5

6 - $x>11$ - $2 x$

$\Rightarrow - x+2 x>11- 6$

$\Rightarrow x>5$.

From (1) and (2), it can be concluded that the solution set for the given system of inequalities is $(5, \infty)$. The solution of the given system of inequalities can be represented on number line as

Answer :

$5(2 x-7)-3(2 x+3) \leq 0$

$\Rightarrow 10 x-35-6 x-9 \leq 0$

$\Rightarrow 4 x-44 \leq 0$

$\Rightarrow 4 x \leq 44$

$\Rightarrow x \leq 11 \ldots$ (1)

$2 x+19 \leq 6 x+47$

$\Rightarrow 19-47$ $\leq x-2 x$

$\Rightarrow-28 \leq x $

$\Rightarrow-7 \leq x$…

From (1) and (2), it can be concluded that the solution set for the given system of inequalities is [-7, 11]. The solution of the given system of inequalities can be represented on number line as

Answer :

Since the solution is to be kept between $68^{\circ} F$ and $77^{\circ} F$,

$68<F<77$

Putting $F=\frac{9}{5} C+32$, we obtain

$68<\frac{9}{5} C+32<77$

$\Rightarrow 68-32<\frac{9}{5} C<77-32$

$\Rightarrow 36<\frac{9}{5} C<45$

$\Rightarrow 36 \times \frac{5}{9}<C<45 \times \frac{5}{9}$

$\Rightarrow 20<C<25$

Thus, the required range of temperature in degree Celsius is between $20^{\circ} C$ and $25^{\circ} C$.

Answer :

Let $x$ litres of $2 %$ boric acid solution is required to be added.

Then,total mixture $=(x+640)$ litres

This resulting mixture is to be more than $4 %$ but less than $6 %$ boric acid.

$\therefore 2 % x+8 %$ of $640>4 %$ of $(x+640)$

And, $2 % x+8 %$ of $640<6 %$ of $(x+640)$

$2 % x+8 %$ of $640>4 %$ of $(x+640)$

$\Rightarrow \frac{2}{100} x+\frac{8}{100}(640)>\frac{4}{100}(x+640)$

$\Rightarrow 2 x+5120>4 x+2560$

$\Rightarrow 5120$ - $2560>4 x - 2 x$

$\Rightarrow 5120$ - $2560>2 x$

$\Rightarrow 2560>2 x$

$\Rightarrow 1280>x$

$2 % x+8 %$ of $640<6 %$ of $(x+640)$

$\frac{2}{100} x+\frac{8}{100}(640)<\frac{6}{100}(x+640)$

$\Rightarrow 2 x+5120<6 x+3840$

$\Rightarrow 5120$ - $3840<6 x - 2 x$

$\Rightarrow 1280<4 x$

$\Rightarrow 320<x$

$\therefore 320<x<1280$

Thus, the number of litres of $2 %$ of boric acid solution that is to be added will have to be more than 320 litres but less than 1280 litres.

Answer :

Let $x$ litres of water is required to be added.

Then,total mixture $=(x+1125)$ litres

It is evident that the amount of acid contained in the resulting mixture is $45 %$ of 1125 litres.

This resulting mixture will contain more than $25 %$ but less than $30 %$ acid content.

$\therefore 30 %$ of $(1125+x)>45 %$ of 1125

And, $25 %$ of $(1125+x)<45 %$ of 1125

$30 %$ of $(1125+x)>45 %$ of 1125 $\Rightarrow \frac{30}{100}(1125+x)>\frac{45}{100} \times 1125$

$\Rightarrow 30(1125+x)>45 \times 1125$

$\Rightarrow 30 \times 1125+30 x>45 \times 1125$

$\Rightarrow 30 x>45 \times 1125-30 \times 1125$

$\Rightarrow 30 x>(45-30) \times 1125$

$\Rightarrow x>\frac{15 \times 1125}{30}=562.5$

$25 %$ of $(1125+x)<45 %$ of 1125

$\Rightarrow \frac{25}{100}(1125+x)<\frac{45}{100} \times 1125$

$\Rightarrow 25(1125+x)>45 \times 1125$

$\Rightarrow 25 \times 1125+25 x>45 \times 1125$

$\Rightarrow 25 x>45 \times 1125-25 \times 1125$

$\Rightarrow 25 x>(45-25) \times 1125$

$\Rightarrow x>\frac{20 \times 1125}{25}=900$

$\therefore 562.5<x<900$

Thus, the required number of litres of water that is to be added will have to be more than 562.5 but less than 900 .

Answer :

It is given that for a group of 12 years old children, $80 \leq IQ \leq 140 \ldots$ (i)

For a group of 12 years old children, $CA=12$ years

$ IQ=\frac{MA}{12} \times 100 $

Putting this value of IQ in (i), we obtain

$ \begin{aligned} & 80 \leq \frac{MA}{12} \times 100 \leq 140 \\ & \Rightarrow 80 \times \frac{12}{100} \leq MA \leq 140 \times \frac{12}{100} \\ & \Rightarrow 9.6 \leq MA \leq 16.8 \end{aligned} $

Thus, the range of mental age of the group of 12 years old children is $9.6 \leq MA \leq 16.8$.