CBSE Class 12 Mathematics Chapter wise Past year questions

5
MCQ · Domain

Domain of f(x) = cos⁻¹ x + sin x is :

(A) R (B) (–1, 1) (C) [–1, 1](D) φ
📖 Show Answer

Answer : (C) [–1, 1]

cos⁻¹ x is defined only when x ∈ [–1, 1].
sin x is defined for all real x.
∴ Domain = [–1, 1] ∩ R = [–1, 1].

6
MCQ · Function Type

If f: NW is defined as

f(n) = { n/2, if n is even
0, if n is odd }

then f is :

(A) injective only(B) surjective only
(C) a bijection (D) neither surjective nor injective
📖 Show Answer

Answer : (D) neither surjective nor injective

Not injective : f(1) = f(3) = 0 but 1 ≠ 3.
Not surjective : 1 ∈ W (codomain) but no n ∈ N gives f(n) = 1.
∴ neither injective nor surjective.

7
MCQ · Relation Properties

If R be a relation defined as aRb iff |a – b| > 0, a, b ∈ R then R is :

(A) reflexive(B) symmetric
(C) transitive(D) symmetric and transitive
📖 Show Answer

Answer : (B) symmetric

Not reflexive : |a – a| = 0 not > 0.
Symmetric : |a – b| > 0 ⇒ |b – a| > 0.
Not transitive : e.g. (1,2) and (2,3) but (1,3) ⇒ |1–3| = 2 > 0 but transitive requires all pairs, counterexample fails.
∴ only symmetric.

8
MCQ · One–one & Onto

For real x, let f(x) = x³ + 5x + 1. Then :

(A) f is one-one but not onto on R
(B) f is onto on R but not one-one
(C) f is one-one and onto on R
(D) f is neither one-one nor onto on R
📖 Show Answer

Answer : (C) f is one-one and onto on R

f'(x) = 3x² + 5 > 0 for all x ∈ R, so f is strictly increasing ⇒ one-one.
Since it’s a cubic polynomial with real coefficients, range = R ⇒ onto.
∴ bijective.

9
Assertion–Reason

Assertion (A) : Let A = {x ∈ R : –1 ≤ x ≤ 1}. If f : A → A be defined as f(x) = x², then f is not an onto function.

Reason (R) : If y = –1 ∈ A, then x = ±√(–1) ∉ A.

📖 Show Answer

Answer : (A) Both A and R are true and R is the correct explanation of A.

f(x) = x² on [–1,1] has range [0,1], not the whole codomain [–1,1].
–1 has no pre-image because x² = –1 has no real solution.
∴ Assertion is true and Reason correctly explains it.

10
Assertion–Reason · Domain

Assertion (A) : Let f(x) = ex and g(x) = log x. Then (f + g)x = ex + log x where domain of (f + g) is R.

Reason (R) : Dom(f + g) = Dom(f) ∩ Dom(g).

📖 Show Answer

Answer : (D) Assertion (A) is false, but Reason (R) is true.

Dom(f) = R, Dom(g) = (0, ∞).
Dom(f+g) = R ∩ (0, ∞) = (0, ∞), not R.
∴ Assertion false, Reason true.

11
Assertion–Reason · Bijective

Assertion (A) : Let Z be the set of integers. A function f : Z → Z defined as f(x) = 3x – 5, ∀ x ∈ Z is a bijective.

Reason (R) : A function is a bijective if it is both surjective and injective.

📖 Show Answer

Answer : (D) Assertion (A) is false, but Reason (R) is true.

f(x) = 3x – 5 is injective on Z but not surjective (e.g. 1 has no pre-image).
So Assertion false. Reason is the correct definition of bijective.

12
Bijection · Logarithm

If f: R+R is defined as f(x) = loga x (a > 0 and a ≠ 1), prove that f is a bijection.

(R+ is the set of all positive real numbers.)

📖 Show Answer

One–one :

Let x₁, x₂ ∈ R+ such that f(x₁) = f(x₂)
⇒ loga x₁ = loga x₂ ⇒ x₁ = x₂.
∴ f is one–one.

Onto :

Let f(x) = y ⇒ loga x = y ⇒ x = ay.
For every y ∈ R, there exists x = ayR+.
∴ f is onto.

Hence f is a bijection.

13
Relation · Domain & Range

Let A = {1, 2, 3} and B = {4, 5, 6}. A relation R from A to B is defined as
R = {(x, y) : x + y = 6, x ∈ A, y ∈ B}.

(i) Write all elements of R.
(ii) Is R a function ? Justify.
(iii) Determine domain and range of R.

📖 Show Answer

(i) Elements of R :

R = {(1,5), (2,4)}

(ii) Is R a function ?

R is not a function as 3 ∈ A does not have an image in co-domain B.

(iii) Domain & Range :

Domain of R = {1, 2},   Range of R = {4, 5}.

14
Relation · Reflexive, Symmetric, Transitive

Let R be a relation defined over N, where N is set of natural numbers, defined as
“mRn if and only if m is a multiple of n, m, n ∈ N.”
Find whether R is reflexive, symmetric and transitive or not.

📖 Show Answer

Reflexive :

Every natural number is a multiple of itself. So xRx. ∴ R is reflexive.

Symmetric :

8 is a multiple of 2 ⇒ 8R2, but 2 is not a multiple of 8.
∴ R is not symmetric.

Transitive :

Let xRy and yRz ⇒ x = my, y = nz ⇒ x = (mn)z ⇒ xRz.
∴ R is transitive.

15
Relation · Irrational Number

Let R be a relation on set of real numbers R defined as
{(x, y) : x – y + √3 is an irrational number, x, y ∈ R}
Verify R for reflexivity, symmetry and transitivity.

📖 Show Answer

Reflexive :

x – x + √3 = √3 is irrational ⇒ (x,x) ∈ R. ∴ R is reflexive.

Symmetric :

(√3, 2) ∈ R because √3 – 2 + √3 = 2(√3 – 1) irrational.
But (2, √3) ∉ R because 2 – √3 + √3 = 2 rational.
∴ R is not symmetric.

Transitive :

Counterexample: (–√3, √3) ∈ R and (√3, 2) ∈ R but (–√3, 2) ∉ R.
∴ R is not transitive.

16
Bijection · Piecewise Function

Show that the function f : NN, where N is a set of natural numbers, given by

f(n) = { n – 1, if n is even
n + 1, if n is odd }

is a bijection.

📖 Show Answer

One–one :

Let f(x) = f(y). If both odd or both even, x = y.
If x odd, y even then x+1 = y–1 ⇒ x–y = –2, not possible.
∴ f is one–one.

Onto :

For every y ∈ N, if y is odd, x = y+1 (even); if y is even, x = y–1 (odd).
Thus every y has a pre-image. So range = N = co-domain.
∴ f is onto.

Hence f is bijective.

17
One–one & Onto · Cubic

Show that the function f : RR defined by f(x) = 4x³ – 5, ∀ x ∈ R is one–one and onto.

📖 Show Answer

One–one :

Let f(x₁) = f(x₂) ⇒ 4x₁³ – 5 = 4x₂³ – 5 ⇒ x₁³ = x₂³ ⇒ x₁ = x₂.
∴ f is one–one.

Onto :

For any y ∈ R, choose x = ∛((y+5)/4) ∈ R.
Then f(x) = y. So range = R = co-domain.
∴ f is onto.

Hence f is both one–one and onto.

18
Relation · Domain, Range, Equivalence

A student wants to pair up natural numbers in such a way that they satisfy the equation 2x + y = 41, x, y ∈ N.
Find the domain and range of the relation. Check if the relation thus formed is reflexive, symmetric and transitive. Hence, state whether it is an equivalence relation or not.

📖 Show Answer

Relation R :

R = {(1,39), (2,37), …, (20,1)}
Domain = {1, 2, 3, …, 20}
Range = {1, 3, 5, …, 39} (odd numbers)

Reflexive :

(1,1) ∉ R ⇒ not reflexive.

Symmetric :

(1,39) ∈ R but (39,1) ∉ R ⇒ not symmetric.

Transitive :

(11,19) ∈ R and (19,3) ∈ R but (11,3) ∉ R ⇒ not transitive.

Hence R is not an equivalence relation.

19
Equivalence Relation · Square Product

Let R be a relation defined on a set N of natural numbers such that
R = {(x, y) : xy is a square of a natural number, x, y ∈ N}.
Determine if the relation R is an equivalence relation.

📖 Show Answer

Reflexive :

x·x = x² is a square ⇒ (x,x) ∈ R. ∴ R is reflexive.

Symmetric :

If xy is a square, then yx is also a square ⇒ (y,x) ∈ R.
∴ R is symmetric.

Transitive :

Let xy = a² and yz = b² ⇒ x = a²/y, z = b²/y.
xz = (ab/y)² ⇒ (x,z) ∈ R.
∴ R is transitive.

Hence R is an equivalence relation.

20
Relations · Reflexive, Symmetric, Transitive

A classroom teacher writes five relations on A = {1, 2, 3}:

R₁ = {(2,3), (3,2)}
R₂ = {(1,2), (1,3), (3,2)}
R₃ = {(1,2), (2,1), (1,1)}
R₄ = {(1,1), (1,2), (3,3), (2,2)}
R₅ = {(1,1), (1,2), (3,3), (2,2), (2,1), (2,3), (3,2)}

(i) Identify the relation which is reflexive, transitive but not symmetric.
(ii) Identify the relation which is reflexive and symmetric but not transitive.
(iii) (a) Identify the relations which are symmetric but neither reflexive nor transitive.

OR

(iii) (b) What pairs should be added to R₂ to make it an equivalence relation ?

📖 Show Answer

(i) R₄

R₄ is reflexive, transitive but not symmetric (1,2) ∈ R₄ but (2,1) ∉ R₄.

(ii) R₅

R₅ is reflexive and symmetric but not transitive (e.g. (1,2) & (2,3) but (1,3) ∉ R₅).

(iii) (a) R₁ and R₃

Both are symmetric but neither reflexive nor transitive.

OR (iii) (b)

Pairs to be added to R₂ : (1,1), (2,2), (3,3), (2,1), (3,1), (2,3)

21
Debate Competition · Relations & Functions

Speakers S = {S₁, S₂, S₃, S₄} and Judges J = {J₁, J₂, J₃}.
R = {(x, y) : speaker x is judged by judge y, x ∈ S, y ∈ J}.

(i) How many relations can be there from S to J ?
(ii) A student identifies a function f = {(S₁, J₁), (S₂, J₂), (S₃, J₂), (S₄, J₃)}. Check if it is bijective.
(iii) (a) How many one-one functions can be there from set S to set J ?

OR

(iii) (b) Another student considers R₁ = {(S₁, S₂), (S₂, S₄)} in set S. Write minimum ordered pairs to be included in R₁ so that R₁ is reflexive but not symmetric.

📖 Show Answer

(i) Number of relations = 24×3 = 212 = 4096

(ii) S₂ and S₃ both map to J₂ ⇒ not one–one. Hence not bijective.

(iii) (a) n(S) = 4, n(J) = 3. Since n(S) > n(J), no one–one function exists. Number = 0.

OR (iii) (b)

To make R₁ reflexive and not symmetric, add : (S₁,S₁), (S₂,S₂), (S₃,S₃), (S₄,S₄).

22
Roll Numbers · Bijection & Relation

Let A be the set of 30 students of class XII. Let f : A → N, f(x) = Roll Number of student x.

(i) Is f a bijective function ?
(ii) Give reasons to support your answer to (i).
(iii) (a) Let R = {(x,y) : x,y are Roll Numbers such that y = 3x}. List elements of R. Is R reflexive, symmetric and transitive ? Justify.

OR

(iii) (b) Let R = {(x,y) : x,y are Roll Numbers such that y = x³}. List elements of R. Is R a function ? Justify.

📖 Show Answer

(i) Yes, f is bijective (assuming roll numbers are 1 to 30, each student has a unique roll number).

(ii) One–one: different students have different roll numbers. Onto: every roll number from 1 to 30 is assigned to a student.

(iii) (a) R = {(1,3), (2,6), (3,9), …, (10,30)}. Not reflexive (1,1) ∉ R. Not symmetric (1,3) ∈ R but (3,1) ∉ R. Not transitive (1,3) and (3,9) but (1,9) ∉ R.

OR (iii) (b) R = {(1,1), (2,8), (3,27)}. Yes, R is a function because each x has exactly one y.