Probability MCQ Questions & Answers in Statistics and Probability | Maths
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151.
A coin is tossed $$n$$ times. The probability of getting at least one head is
greater than that of getting at least two tails by $$\frac{5}{{32}}.$$ Then $$n$$ is :
A
$$5$$
B
$$10$$
C
$$15$$
D
none of these
Answer :
$$5$$
The probability of getting at least one head
$$ = 1 - $$ probability of getting no heads
$$\eqalign{
& = 1 - {}^n{C_0}{\left( {\frac{1}{2}} \right)^0}.{\left( {\frac{1}{2}} \right)^n} \cr
& = 1 - \frac{1}{{{2^n}}} \cr} $$
The probability of getting at least two tails
$$ = 1 - $$ probability of getting no tails $$-$$ probability of getting $$1$$ tail
$$\eqalign{
& = 1 - {}^n{C_n}{\left( {\frac{1}{2}} \right)^n}.{\left( {\frac{1}{2}} \right)^0} - {}^n{C_{n - 1}}{\left( {\frac{1}{2}} \right)^{n - 1}}.\frac{1}{2} \cr
& = 1 - \frac{1}{{{2^n}}} - n\frac{1}{{{2^n}}} \cr} $$
From the question,
$$\eqalign{
& \left( {1 - \frac{1}{{{2^n}}}} \right) - \left( {1 - \frac{{1 + n}}{{{2^n}}}} \right) = \frac{5}{{12}} \cr
& {\text{or }}\frac{{n + 1}}{{{2^n}}} - \frac{1}{{{2^n}}} = \frac{5}{{32}} \cr
& {\text{or }}\frac{n}{{{2^n}}} = \frac{5}{{32}}\,\,\,\,\,\,\, \Rightarrow n = 5 \cr} $$
152.
In four schools $${B_1},\,{B_2},\,{B_3},\,{B_4}$$ the percentage of girls students is $$12,\,20,\,13,\,17$$ respectively. From a school
selected at random, one student is picked up at random and it is found that the student is a girl. The probability that the school selected is $${B_2},$$ is :
A
$$\frac{6}{{31}}$$
B
$$\frac{{10}}{{31}}$$
C
$$\frac{{13}}{{62}}$$
D
$$\frac{{17}}{{62}}$$
Answer :
$$\frac{{10}}{{31}}$$
Total number of students in four schools $$ = 12 + 20 + 13 + 17 = 62$$
Now, one student is selected at random.
$$\therefore $$ Total outcomes $$ = {}^{62}{C_1}$$
Now, number of students in school $${B_2} = 20$$
Number of ways to select a student from $${B_2} = {}^{20}{C_1}$$
$$\therefore $$ Required probability $$ = \frac{{{}^{20}{C_1}}}{{{}^{62}{C_1}}} = \frac{{20}}{{62}} = \frac{{10}}{{31}}$$
153.
From a group of $$10$$ persons consisting of $$5$$ lawyers, $$3$$ doctors and $$2$$ engineers, four persons are selected at random. The probability that the selection contains at least one of each category is :
154.
A computer producing factory has only two plants $${T_1}$$ and $${T_2}.$$ Plant $${T_1}$$ produces 20% and plant $${T_2}$$ produces 80% of the total computers produced. 7% of computers produced in the factory turn out to be defective. It is known that $$P$$ (computer turns out to be defective given that it is produced in plant $${T_1}$$)
= 10$$P$$ (computer turns out to be defective given that it is produced in plant $${T_2}$$),
where $$P(E)$$ denotes the probability of an event $$E.$$ A computer produced in the factory is randomly selected and it does not turn out to be defective. Then the probability that it is produced in plant $${T_2}$$ is
Note :- The question should state ‘3 different’ boxes instead of ‘3 identical boxes’ and one particular box has 3 balls. Then the solution would be:
Required probability $$ = \frac{{^{12}{C_3} \times {2^9}}}{{{3^{12}}}} = \frac{{55}}{3}{\left( {\frac{2}{3}} \right)^{11}}$$
156.
Two cards are drawn at random from a pack of $$52$$ cards. The probability of getting at least a spade and an ace is :
A
$$\frac{1}{{34}}$$
B
$$\frac{8}{{221}}$$
C
$$\frac{1}{{26}}$$
D
$$\frac{2}{{51}}$$
Answer :
$$\frac{1}{{26}}$$
$$n\left( S \right) = {}^{52}{C_2}{\text{ and}}$$
$$n\left( E \right) = $$ the number of selections of $$1$$ spade, $$1$$ ace from $$3$$ aces or selections of the ace of spade and $$1$$ other spade
$$\eqalign{
& \,\,\,\,\,\,\,\,\,\,\,\,\,\,\, = {}^{13}{C_1} \times {}^3{C_1} + {}^{12}{C_1} \times {}^1{C_1} = 51 \cr
& \therefore \,\,\,\,P\left( E \right) = \frac{{51}}{{{}^{52}{C_2}}} = \frac{1}{{26}}. \cr} $$
157.
It has been found that if $$A$$ and $$B$$ play a game $$12$$ times, $$A$$ wins $$6$$ times, $$B$$ wins $$4$$ times and they draw twice. $$A$$ and $$B$$ take part in a series of $$3$$ games. The probability that they win alternately, is :
158.
If the integers $$m$$ and $$n$$ are chosen at random between $$1$$ and $$100$$ then the probability that a number of the form $${7^m} + {7^n}$$ is divisible by $$5$$ is :
A
$$\frac{1}{5}$$
B
$$\frac{1}{7}$$
C
$$\frac{1}{4}$$
D
$$\frac{1}{{49}}$$
Answer :
$$\frac{1}{5}$$
We know $${7^k},\,k\, \in \,N,$$ has $$1,\,3,\,9,\,7$$ at the units place for $$k = 4p,\,4p - 1,\,4p - 2,\,4p - 3$$ respectively, where $$p = 1,\,2,\,3,.....$$
Clearly, $${7^m} + {7^n}$$ will be divisible by $$5$$ if $${7^m}$$ has $$3$$ or $$7$$ in the units place and $${7^n}$$ has $$7$$ or $$3$$ in the units place or $${7^m}$$ has $$1$$ or $$9$$ in the units place and $${7^n}$$ has $$9$$ or $$1$$ in the units place.
$$\therefore $$ for any choice of $$m,\,n$$ the digit in the units place of $${7^m} + {7^n}$$ is $$2,\,4,\,6,\,0$$ or $$8.$$ It is divisible by $$5$$ only when this digit is $$0.$$
$$\therefore $$ the required probability $$ = \frac{1}{5}.$$
159.
A bag contains $$50$$ tickets numbered $$1,\,2,\,3,\,.....,\,50$$ of which five are drawn at random and arranged in ascending order of magnitude $$\left( {{x_1} < {x_2} < {x_3} < {x_4} < {x_5}} \right).$$ The probability that $${x_3} = 30$$ is :
A
$$\frac{{{}^{20}{C_2}}}{{{}^{50}{C_5}}}$$
B
$$\frac{{{}^2{C_2}}}{{{}^{50}{C_5}}}$$
C
$$\frac{{{}^{20}{C_2} \times {}^{29}{C_2}}}{{{}^{50}{C_5}}}$$
Five tickets out of $$50$$ can drawn in $${{}^{50}{C_5}}$$ ways.
Since $${{x_1} < {x_2} < {x_3} < {x_4} < {x_5}}$$ and $${x_3} = 30,\,{x_1},\,{x_2} < 30,$$ i.e., $${x_1}$$ and $${x_2}$$ should come from tickets numbered $$1$$ and $$29$$ and this may happen in $${{}^{29}{C_2}}$$ ways.
Remaining ways, i.e., $${x_4},\,{x_5} > 30,$$ should come from $$20$$ tickets numbered $$31$$ to $$50$$ in $${{}^{20}{C_2}}$$ ways.
So, favourable number of cases $$ = {}^{29}{C_2}{}^{29}{C_2}$$
Hence, required probability $$ = \frac{{{}^{20}{C_2} \times {}^{29}{C_2}}}{{{}^{50}{C_5}}}$$
160.
A bag contains an assortment of blue and red balls. If two balls are drawn at random, the probability of drawing two red balls is five times the probability of drawing two blue balls. Furthermore, the probability of drawing one ball of each color is six times the probability of drawing two blue balls. The number of red and blue balls in the bag is :
A
$$6,\,3$$
B
$$3,\,6$$
C
$$2,\,7$$
D
none of these
Answer :
$$6,\,3$$
Let the number of red and blue balls be $$r$$ and $$b$$, respectively. Then, the probability of drawing two red balls
$$ = {p_1} = \frac{{{}^r{C_2}}}{{{}^{r + b}{C_2}}} = \frac{{r\left( {r - 1} \right)}}{{\left( {r + b} \right)\left( {r + b - 1} \right)}}$$
The probability of drawing two blue balls is
$$ = {p_2} = \frac{{{}^b{C_2}}}{{{}^{r + b}{C_2}}} = \frac{{b\left( {b - 1} \right)}}{{\left( {r + b} \right)\left( {r + b - 1} \right)}}$$
The probability of drawing one red and one blue ball
$$ = {p_3} = \frac{{{}^r{C_1}{}^b{C_1}}}{{{}^{r + b}{C_2}}} = \frac{{2br}}{{\left( {r + b} \right)\left( {r + b - 1} \right)}}$$
By hypothesis, $${p_1} = 5{p_2}$$ and $${p_3} = 6{p_2}.$$
Therefore, $$r\left( {r - 1} \right) = 5b\left( {b - 1} \right)$$ and $$2br = 6b\left( {b - 1} \right) \Rightarrow r = 6,\,b = 3.$$