Sets and Relations MCQ Questions & Answers in Calculus | Maths
Learn Sets and Relations MCQ questions & answers in Calculus are available for students perparing for IIT-JEE and engineering Enternace exam.
111.
A market research group conducted a survey of 2000 consumers and reported that 1720 consumers like product $${P_1}$$ and 1450 consumers like product $${P_2}.$$ What is the least number that must have liked both the products ?
A
1150
B
2000
C
1170
D
2500
Answer :
1170
Let $$U$$ be the set of all consumers who were questioned, $$A$$ be the set of consumers who liked product $${P_1}$$ and $$B$$ be the set of consumers who liked product $${P_2}.$$
It is given that
$$\eqalign{
& n\left( U \right) = 2000,\,\,n{\left( A \right)} = 1720,\,\,n\left( B \right) = 1450, \cr
& n\left( {A \cup B} \right) = n\left( A \right) + n\left( B \right) - n\left( {A \cap B} \right) \cr
& = 1720 + 1450 - n\left( {A \cap B} \right) \cr
& = 3170 - n\left( {A \cap B} \right) \cr
& {\text{Since,}}\,A \cup B \subseteq U\,\,\,\therefore \,\,n\left( {A \cup B} \right) \leqslant n\left( U \right) \cr
& \Rightarrow \,3170 - n\left( {A \cap B} \right) \leqslant 2000 \cr
& \Rightarrow \,3170 - 2000 \leqslant n\left( {A \cap B} \right) \cr
& \Rightarrow n\left( {A \cap B} \right) \geqslant 1170 \cr} $$
Thus, the least value of $$n\left( {A \cap B} \right)$$ is 1170.
Hence, the least number of consumers who liked both the products is 1170.
112.
In a town of 10000 families, is was found that $$40\%$$ families buy newspaper $$A,\,20\%$$ families buy news paper $$B$$ and $$10\%$$ families buy newspaper $$C,\,5\%$$ buy $$A$$ and $$B,\,3\%$$ buy $$B$$ and $$C$$ and $$4\%$$ buy $$A$$ and $$C$$. If $$2\%$$ families buy all of three newspapers, then the number of families which buy $$A$$ only, is :
113.
Let $$R$$ be the set of real numbers. Statement - 1: $$A$$ = {($$x, y$$ ) $$ \in R \times R:$$ $$y - x$$ is an integer} is an equivalence relation on $$R.$$ Statement - 2 : $$B$$ = {($$x, y$$ ) $$ \in R \times R:$$ $$x = \alpha y$$ for some rational number $$\alpha $$ } is an equivalence relation on $$R.$$
A
Statement - 1 is true, Statement - 2 is true; Statement - 2 is not a correct explanation for Statement - 1.
B
Statement - 1 is true, Statement - 2 is false.
C
Statement - 1 is false, Statement - 2 is true.
D
Statement - 1 is true, Statement - 2 is true; Statement - 2 is a correct explanation for Statement - 1.
Answer :
Statement - 1 is true, Statement - 2 is false.
$$x - y$$ is an integer.
$$\because \,\,x - x = 0$$ is an integer
⇒ $$A$$ is reflexive.
Let $$x - y$$ is an integer
⇒ $$y - x$$ is an integer
⇒ $$A$$ is symmetric
Let $$x - y, y - z$$ is also an integer
⇒ $$x - y + y - z$$ is also an integer
⇒ $$x - z$$ is an integer
⇒ $$A$$ is transitive
∴ $$A$$ is an equivalence relation.
Hence statement - 1 is true.
Also $$B$$ can be considered as
$$xBy$$ if $$\frac{x}{y} = \alpha ,$$ a rational number
$$\because \,\,\frac{x}{x} = 1$$ is a rational number
⇒ $$B$$ is reflexive
But $$\frac{x}{y} = \alpha ,$$ a rational number need not imply $$\frac{y}{x} = \frac{1}{\alpha },$$ a rational number because
$$\frac{0}{1}$$ is rational
⇒ $$\frac{1}{0}$$ is not rational
∴ $$B$$ is not an equivalence relation.
114.
In a B school there are 15 teachers who teach marketing or finance. Of these, 8 teach finance and 4 teach both marketing and finance. How many teach marketing but not finance ?
A
15
B
20
C
11
D
none of these
Answer :
11
From the given condition $$n\left( {M \cup F} \right) = 15,\,\,n\left( F \right) = 8,\,\,n\left( {M \cap F} \right) = 4$$
$$\eqalign{
& {\text{So, }}n\left( {M \cup F} \right) = n\left( M \right) + n\left( F \right) - n\left( {M \cap F} \right) \cr
& {\text{or, }}n\left( M \right) = n\left( {M \cup F} \right) + n\left( {M \cap F} \right) - n\left( F \right) \cr
& {\text{hence }}n\left( M \right) = 15 + 4 - 8 = 11 \cr} $$
115.
Let $$f:{\bf{R}} \to {\bf{R}}$$ be a function such that $$f\left( x \right) = ax + 3\,\sin \,x + 4\,\cos \,x.$$ Then $$f\left( x \right)$$ is invertible if :
$$f'\left( x \right) = ax + 3\,\cos \,x + 4\,\sin \,x$$
$$f\left( x \right)$$ is one-one if $$f'\left( x \right) > 0$$ for all $$x$$ or $$f'\left( x \right) < 0$$ for all $$x.$$
Now, $$ - 5 \leqslant 3\,\cos \,x - 4\,\sin \,x \leqslant 5$$
$$\eqalign{
& {\text{So, }}f'\left( x \right) < 0\,\forall \,x,{\text{ if }}a < - 5{\text{ and }}f'\left( x \right) > 0\,\forall \,x,{\text{ if }}a > 5 \cr
& \therefore \,a\, \in \left( { - \infty ,\, - 5} \right) \cup \left( {5,\,\infty } \right) \cr} $$
116.
Consider the following statements. I. If $${A_n}$$ is the set of first $$n$$ prime numbers then $$\mathop U\limits_{n = 2}^{10} \,{A_n}$$ is equal to $$\left\{ {2,\,3,\,5,\,7,\,11,\,13,\,17,\,19,\,23,\,29} \right\}$$ II. if $$A$$ and $$B$$ are two sets such that $$n\left( {A \cup B} \right) = 50,\,\,n\left( A \right) = 28,\,\,n\left( B \right) = 32,$$ then $$n\left( {A \cap B} \right) = 10$$
Which of these is correct ?
A
Only I is true
B
Only II is true
C
Both are true
D
Both are false
Answer :
Both are true
$$\eqalign{
& {\text{I}}{\text{.}}\,\,\,\mathop U\limits_{n = 2}^{10} \,{A_n}{\text{ is the set of first 10 prime numbers}} \cr
& = \left\{ {2,\,3,\,5,\,7,\,11,\,13,\,17,\,19,\,23,\,29} \right\} \cr
& {\text{II}}{\text{.}}\,\,n\left( {A \cup B} \right) = n\left( A \right) + n\left( B \right) - n\left( {A \cap B} \right) \cr
& \Rightarrow 50 = 28 + 32 - n\left( {A \cap B} \right) \cr
& \Rightarrow n\left( {A \cap B} \right) = 60 - 50 = 10 \cr} $$
117.
Out of 32 persons, 30 invest in National Savings Certificates and 17 invest in shares. What is the number of persons who invest in both ?
A
13
B
15
C
17
D
19
Answer :
15
Let $$N = $$ National Savings Certificates
$$S = $$ Shares
Total number of persons $$ = 32$$
Number of persons who invest in National Savings Certificates $$ = 30$$
Number of persons who invest in Shares $$ = 17$$
Therefore
$$n\left( {N \cup S} \right) = 32,\,\,n\left( N \right) = 30,\,\,n\left( S \right) = 17$$
We know that,
$$\eqalign{
& n\left( {N \cup S} \right) = n\left( N \right) + n\left( S \right) - n\left( {N \cap S} \right) \cr
& \Rightarrow 32 = 30 + 17 - n\left( {N \cap S} \right) \cr
& \Rightarrow n\left( {N \cap S} \right) = 47 - 32 = 15 \cr} $$
118.
Let $$X$$ = {1, 2, 3, 4, 5}. The number of different ordered pairs $$(Y, Z)$$ that can formed such that $$Y \subseteq X,Z \subseteq X$$ and $$Y \cap Z$$ empty is :
A
$${5^2}$$
B
$${3^5}$$
C
$${2^5}$$
D
$${5^3}$$
Answer :
$${3^5}$$
Let $$X$$ = {1, 2, 3, 4, 5}
Total no. of elements = 5
Each element has 3 options. Either set $$Y$$ or set $$Z$$ or none. $$\left( {\because Y \cap Z = \phi } \right)$$
So, number of ordered pairs $$ = {3^5}$$
119.
If $$A$$ and $$B$$ are two sets, then $$\left( {A - B} \right) \cup \left( {B - A} \right) \cup \left( {A \cap B} \right)$$ is equal to :
120.
Which of the following is correct ? I. $$n\left( {S \cup T} \right)$$ is maximum when $$n\left( {S \cap T} \right)$$ is least. II. If $$n\left( U \right) = 1000,\,n\left( S \right) = 720,\,n\left( T \right) = 450,$$ then least value of $$n\left( {S \cap T} \right) = 170$$