Buy BOOKS at Discounted Price

Relations And Functions

Class 12th Mathematics NCERT Exemplar Solution
Exercise
  1. Let A = {a, b, c} and the relation R be defined on A as follows: R = {(a, a), (b,…
  2. Let D be the domain of the real valued function f defined by f (x) = root 25-x^2 .…
  3. Let f, g :R → R be defined by f(x) = 2x + 1 and g (x) = x^2 - 2, i∀ x ∈ R,…
  4. Let f :R → R be the function defined by f (x) = 2x - 3 ∀ x ∈ R. write f-1.…
  5. If A = {a, b, c, d} and the function f = {(a, b), (b, d), (c, a), (d, c)}, write…
  6. If f :R → R is defined by f (x) = x^2 - 3x + 2, write f (f (x)).
  7. Is g = {(1, 1), (2, 3), (3, 5), (4, 7)} a function? If g is described by g (x) = α…
  8. Are the following set of ordered pairs functions? If so, examine whether the…
  9. If the mappings f and g are given by f = {(1, 2), (3, 5), (4, 1)} and g = {(2, 3),…
  10. Let C be the set of complex numbers. Prove that the mapping f :C → R given by f…
  11. Let the function f :R → R be defined by f (x) = cosx, ∀ x ∈ R. Show that f is…
  12. Let X = {1, 2, 3} and Y = {4, 5}. Find whether the following subsets of X × Y are…
  13. If functions f : A → B and g : B → A satisfy g o f = IA, then show that f is one…
  14. Let f : R → R be the function defined by f (x) = 1/2-cosx for all x inr . Then,…
  15. Let n be a fixed positive integer. Define a relation R in Z as follows: ∀ a, b…
  16. If A = {1, 2, 3, 4 }, define relations on A which have properties of being: (a)…
  17. Let R be relation defined on the set of natural number N as follows: R = {(x, y):…
  18. Given A = {2, 3, 4}, B = {2, 5, 6, 7}. Construct an example of each of the…
  19. which is one-one but not onto Give an example of a map
  20. which is not one-one but onto Give an example of a map
  21. which is neither one-one nor onto. Give an example of a map
  22. Let A = R - {3}, B = R - {1}. Let f : A → B be defined by f (x) = x-2/x-3 ∀ x ∈ A…
  23. f (x) = x/2 Let A = [-1, 1]. Then, discuss whether the following functions…
  24. g(x) = |x| Let A = [-1, 1]. Then, discuss whether the following functions…
  25. h(x) = x |x| Let A = [-1, 1]. Then, discuss whether the following functions…
  26. k(x) = x^2 Let A = [-1, 1]. Then, discuss whether the following functions…
  27. x is greater than y, x, y ∈N Determine which of the above relations are…
  28. x + y = 10, x, y ∈N Determine which of the above relations are reflexive,…
  29. x y is square of an integer x, y ∈N Determine which of the above relations are…
  30. x + 4y = 10 x, y ∈N. Determine which of the above relations are reflexive,…
  31. Let A = {1, 2, 3, ... 9} and R be the relation in A ×A defined by (a, b) R (c, d)…
  32. Using the definition, prove that the function f : A → B is invertible if and only…
  33. Functions f, g : R → R are defined, respectively, by f (x) = x^2 + 3x + 1, g (x)…
  34. Let * be the binary operation defined on Q. Find which of the following binary…
  35. Let * be binary operation defined on R by a * b = 1 + ab, ∀a, b ∈R. Then the…
  36. Let T be the set of all triangles in the Euclidean plane, and let a relation R on…
  37. Consider the non-empty set consisting of children in a family and a relation R…
  38. The maximum number of equivalence relations on the set A = {1, 2, 3} areA. 1 B. 2…
  39. If a relation R on the set {1, 2, 3} be defined by R = {(1, 2)}, then R isA.…
  40. Let us define a relation R in R as aRb if a ≥ b. Then R isA. an equivalence…
  41. Let A = {1, 2, 3} and consider the relation R = {1, 1), (2, 2), (3, 3), (1, 2),…
  42. The identity element for the binary operation * defined on Q ~ {0} as a^there…
  43. If the set A contains 5 elements and the set B contains 6 elements, then the…
  44. Let A = {1, 2, 3, ...n} and B = {a, b}. Then the number of surjections from A…
  45. Let f :R → R be defined by f (x) = 1/x for all x inr Then f isA. one-one B. onto…
  46. Let f :R → R be defined by f (x) = 3x^2 - 5 and g : R → R by g (x) = x/x^2 + 1 .…
  47. Which of the following functions from Z into Z are bijections?A. f (x) = x^3 B. f…
  48. Let f :R → R be the functions defined by f (x) = x^3 + 5. Then f-1 (x) isA.…
  49. Let f : A → B and g : B → C be the bijective functions. Then (g o f)-1 isA. f-1 o…
  50. Let f:r - 3/5 arrowr be defined by f (x) = 3x+2/5x-3 . ThenA. f-1 (x) = f (x) B.…
  51. Let f : [0, 1] → [0, 1] be defined by f (x) = x , x 1-x , x Then (f o f) x isA.…
  52. Let f : [2, ∞) → R be the function defined by f (x) = x^2 -4x+5, then the range…
  53. Let f : N → R be the function defined by f (x) = 2x-1/2 and g : Q → R be another…
  54. Let f :R → R be defined by f (x) = 2x:x3 x^2 :1x less than equal to 3 3x:x less…
  55. Let f :R → R be given by f (x) = tan x. Then f-1 (1) isA. π/4 B. n pi + pi /4 n…
  56. Let the relation R be defined in N by aRb if 2a + 3b = 30. Then R = ______. Fill…
  57. Let the relation R be defined on the set A = {1, 2, 3, 4, 5} by R = {(a, b) :…
  58. Let f = {(1, 2), (3, 5), (4, 1) and g = {(2, 3), (5, 1), (1, 3)}. Then g o f =…
  59. Let f :R → R be defined by f (x) = x/root 1+x^2 . Then (f o f o f) (x) = _______…
  60. If f (x) = {4 - (x-7)^3 }, then f-1(x) = _______. Fill in the blanks in each of…
  61. Let R = {(3, 1), (1, 3), (3, 3)} be a relation defined on the set A = {1, 2, 3}.…
  62. Let f : R → R be the function defined by f (x) = sin (3x+2)∀x ∈R. Then f is…
  63. Every relation which is symmetric and transitive is also reflexive. State True or…
  64. An integer m is said to be related to another integer n if m is a integral…
  65. Let A = {0, 1} and N be the set of natural numbers. Then the mapping f :N → A…
  66. The relation R on the set A = {1, 2, 3} defined as R = {{1, 1), (1, 2), (2, 1),…
  67. The composition of functions is commutative. State True or False for the…
  68. The composition of functions is associative. State True or False for the…
  69. Every function is invertible. State True or False for the statements…
  70. A binary operation on a set has always the identity element. State True or False…

Exercise
Question 1.

Let A = {a, b, c} and the relation R be defined on A as follows:

R = {(a, a), (b, c), (a, b)}.

Then, write minimum number of ordered pairs to be added in R to make R reflexive and transitive.


Answer:

A relation R on a set A is said to be reflexive if every element of A is related to itself.


Thus, R is reflexive, iff (a, a) ∈ R, for every a ∈ A


We have,


A = {a, b, c} and R = {(a, a), (b, c), (a, b)}


Therefore by definition of reflexive relation, if a, b, c ∈ A then (a, a),(b, b) and (c, c) ∈ R.


We observe that since (b, b) and (c, c) does not belong to R so R is not reflexive. We need to add (b, b) and (c, c) in R in order to make it reflexive.


A relation R on a set A is said to be transitive iff aRb and bRc then aRc for all a,b,c ∈ A


i.e., (a, b) ∈ R and (b, c) ∈ R


⇒ (a, c) ∈ R for all a,b,c ∈ A


We observe that since (a, c) does not belong to R so R is not transitive. We need to add (a, c) in R in order to make it transitive.


Hence, minimum number of ordered pairs to be added in R to make R reflexive and transitive are (b, b), (c, c) and (a, c).


Now, R = {(a, a), (b, b), (c, c), (a, c), (b, c), (a, b)} is Reflexive and Transitive.



Question 2.

Let D be the domain of the real valued function f defined by . Then, write D.


Answer:

The set of values​​for which the function can be defined is domain of a real valued function.


We have,


In order to find domain of f(x) we need to find those real values of x which will give real value to f(x) after solving.


Now, f is a real valued function if 25-x2 ≥ 0


⇒ 25-x2 ≥ 0


⇒ -(x2-25) ≥ 0


On multiplying the inequality by -1 we get,


⇒ x2-25 ≤ 0


Note : The sign of inequality is reversed if it is multiplied by a negative quantity.


⇒ (x+5)(x-5) ≤ 0


⇒ x ∈ [-5,5]


Hence, Domain(f) = {x : x ∈ [-5,5] }



Question 3.

Let f, g :R → R be defined by f(x) = 2x + 1 and g (x) = x2 – 2, i∀ x ∈ R, respectively. Then, find g o f.


Answer:

We have,


gof(x) = g(f(x))


⇒ gof(x) = g(2x+1)


= (2x+1)2 – 2


= (4x2+1+4x) – 2


= 4x2+4x-1


∴ gof = 4x2+4x-1



Question 4.

Let f :R → R be the function defined by f (x) = 2x – 3 ∀ x ∈ R. write f–1.


Answer:

Given that f(x) = 2x-3


Let f(x) = y, then 2x-3 = y



[∵ f(x) = y, ⇒ x = f-1(y)]


Hence, f-1 : R → R is given by



Question 5.

If A = {a, b, c, d} and the function f = {(a, b), (b, d), (c, a), (d, c)}, write f–1.


Answer:

We have, f = {(a, b), (b, d), (c, a), (d, c)}


We can get f-1 by interchanging the components of ordered pairs in f


∴ f-1 = {(b, a), (d, b), (a, c), (c, d)}



Question 6.

If f :R → R is defined by f (x) = x2 – 3x + 2, write f (f (x)).


Answer:

We have,


f(x) = x2 – 3x + 2


∴ f(f(x)) = f (x2 – 3x + 2)


= (x2 – 3x + 2)2 – 3(x2 – 3x + 2) + 2


= x4 + 9x2 + 4 – 6x3 – 12x + 4x2 – 3x2 + 9x – 6 + 2


= x4 – 6x3 + 10x2 – 3x


⇒ f(f(x)) = x4 – 6x3 + 10x2 – 3x



Question 7.

Is g = {(1, 1), (2, 3), (3, 5), (4, 7)} a function? If g is described by g (x) = α x + β, then what value should be assigned to α and β.


Answer:

In order to determine if g = {(1, 1), (2, 3), (3, 5), (4, 7)} represents a function or not, we need to validate if g satisfies the condition of a relation to be a function.


A relation f from a set A to a set B is said to be a function if every


element of set A has one and only one image in set B.


By definition of function we can say that no two distinct ordered pairs in a function have the same first element.


We have,


g = {(1, 1), (2, 3), (3, 5), (4, 7)}


we observe that each first element of ordered pairs is related to only one element.


Hence, g is a function.


Given,


g(x) = α x + β and g(1) = 1


⇒ α + β = 1 ……(i)


g(2) = 3, we get


⇒ α 2 + β = 3 ……(ii)


g(3) = 5, we get


⇒ α 3 + β = 5 ……(iii)


g(4) = 7, we get


⇒ α 4 + β = 7 ……(iv)


Solve any 2 equations from (i),(ii),(iii) and (iv) to find two unknowns α and β


On solving (i) and (ii), we get


α = 2 and β = -1


Hence, the function g(x) = 2x – 1



Question 8.

Are the following set of ordered pairs functions? If so, examine whether the mapping is injective or surjective.

(i) {(x, y): x is a person, y is the mother of x}.

(ii){(a, b): a is a person, b is an ancestor of a}.


Answer:

(i){(x, y): x is a person, y is the mother of x}.


Here, (x, y) is an ordered pair which associates each person (x) to his(her) mother (y).


Now, each person will have only one mother so we can say that for each value of x there is an association to a unique value of y.


Hence,(x, y) represent a function.


Also, more than one person may have same mother.


i.e., two or more distinct value of x may have same value of y.


So, (x, y) is many-one function or surjective.


(ii){(a, b): a is a person, b is an ancestor of a}.


Here, (a, b) is an ordered pair which associates each person (a) to his(her) ancestor (b).


Now, any person can have more than one ancestor so we can say that each value of a does not have a unique value of b.


Hence, (a,b) does not represent a function.



Question 9.

If the mappings f and g are given by f = {(1, 2), (3, 5), (4, 1)} and g = {(2, 3), (5, 1), (1, 3)}, write f o g.


Answer:

We have,


f = {(1, 2), (3, 5), (4, 1)} and g = {(2, 3), (5, 1), (1, 3)}


Domain of g = {2,5,1}


Now, fog(2) = f(g(2)) = f(3) = 5


fog(5) = f(g(5)) = f(1) = 2


fog(1) = f(g(1)) = f(3) = 5


∴ fog = {(2, 5), (5, 2), (1,5) }



Question 10.

Let C be the set of complex numbers. Prove that the mapping f :C → R given by f (z) = |z|, ∀ z ∈ C, is neither one-one nor onto.


Answer:

We have,


f : C → R given by f (z) = |z|, ∀ z ∈ C


In order to prove that f is one-one, it is sufficient to prove that f(z1)=f(z2) ⇒ z1=z2∀ z1, z2 ∈ C .


Let z1 = 2+3i and z2 = 2-3i are two distinct complex numbers.


Now,


f(z1) = |z1| = |2+3i | = = √ 13


f(z2) = |z2| = |2-3i | = = √ 13


here, we observe that f(z1) = f(z2) but z1 ≠ z2


This shows that different element of C may have the same value in R.


Thus, f(z) is not one-one.


f is onto if every element of R is the f-image of some element of C.


We have, f(z) = |z|, ∀ z ∈ C and |z| ≥ 0


We observe that negative real numbers in R do not have their pre-images in C.


Thus, f is not onto.


Hence, f(z) is neither one-one nor onto.



Question 11.

Let the function f :R → R be defined by f (x) = cosx, ∀ x ∈ R. Show that f is neither one-one nor onto.


Answer:

We have,


f (x) = cosx, ∀ x ∈ R


In order to prove that f is one-one, it is sufficient to prove that f(x1)=f(x2) ⇒ x1=x2∀ x1, x2 ∈ A .


Let x1 = 0 and x2 = 2π are two different elements in R.


Now,


f(x1) = f(0) = cos0 = 1


f(x2) = f(2π) = cos2π = 1


we observe that f(x1)=f(x2) but x1 ≠ x2.


This shows that different element in R may have same image.


Thus, f(x) is not one-one.


We know that cosx lies between -1 and 1.


So, the range of f is [-1,1] which is not equal to its co-domain.


i.e., range of f ≠ R (co-domain)


In other words, range of f is less than co-domain, i.e there are elements in co-domain which does not have any pre-image in domain.


so, f is not onto.


Hence, f is neither one-one nor onto.



Question 12.

Let X = {1, 2, 3} and Y = {4, 5}. Find whether the following subsets of X × Y are functions from X to Y or not.

(i) f = {(1, 4), (1, 5), (2, 4), (3, 5)}

(ii) g = {(1, 4), (2, 4), (3, 4)}

(iii) h = {(1,4), (2, 5), (3, 5)}

(iv) k = {(1,4), (2, 5)}.


Answer:

We have,


X = {1, 2, 3} and Y = {4, 5}


∴ X × Y = {(1, 4),(1, 5),(2, 4),(2, 5),(3, 4),(3, 5)}


(i) f = {(1, 4), (1, 5), (2, 4), (3, 5)}


Now, f(1) = 4 and f(1) = 5


We observe that one element of domain maps to two distinct values.


i.e., ‘1’ has no unique image.


Thus, f is not a function.


(ii) g = {(1, 4), (2, 4), (3, 4)}


Now, g(1) = 4, g(2) = 4, g(3) = 4


We observe that each distinct element of domain has unique image.


Thus, g is a function.


(iii) h = {(1,4), (2, 5), (3, 5)}


Now, h(1) = 4, h(2) = 5, h(3) = 5


We observe that each distinct element of domain has unique image.


Thus, h is a function.


(iv) k = {(1,4), (2, 5)}.


Now, k(1) = 4 and k(2) = 5


We observe that ‘3’ does not have any image under the mapping.


Thus, k is not a function.



Question 13.

If functions f : A → B and g : B → A satisfy g o f = IA, then show that f is one one and g is onto.


Answer:

Given : gof = IA


In order to prove that f is one-one, it is sufficient to prove that f(x)=f(y) ⇒ x=y ∀ x,y ∈ A .


Let x,y ∈ A such that f(x) = f(y). Then,


f(x) = f(y)


⇒ g(f(x)) = g(f(y))


⇒ gof(x) = gof(y)


⇒ IA(x) = IA(y) [∵ gof = IA is given ]


⇒ x = y [by definition of Identity function, I(x) = x]


Thus, f is one-one.


Now, in order to prove that g : B → A is onto, it is sufficient to prove that each element in A has pre-image in B.


Let x ∈ A.


Also, f : A → B is a function ∴ f(x) ∈ B


Now,


Let f(x) = y


⇒ g(f(x)) = g(y)


⇒ gof(x) = g(y)


⇒ IA(x) = g(y) [∵ gof = IA is given ]


⇒ x = g(y) [by definition of Identity function, I(x) = x]


Thus, for every x ∈ A there exists y ∈ B such that g(y) = x.


⇒ g is onto.



Question 14.

Let f : R → R be the function defined by . Then, find the range of f.


Answer:

We have,


Let


⇒ 2y–ycosx = 1


⇒ -ycosx = 1-2y




Now, we know that range of cosx is [-1,1].


⇒ -1 ≤ cosx ≤ 1




On multiplying the inequality by -1 we get,



Note : The sign of inequality is reversed if it is multiplied by a negative quantity.




Thus, range of



Question 15.

Let n be a fixed positive integer. Define a relation R in Z as follows: ∀ a, b ∈Z, aRb if and only if a – b is divisible by n. Show that R is an equivalence relation.


Answer:

In order to show R is an equivalence relation we need to show R is Reflexive, Symmetric and Transitive.


Given that, ∀ a, b ∈Z, aRb if and only if a – b is divisible by n.


Now,


R is Reflexive if (a,a)RaZ


aRa ⇒ (a-a) is divisible by n.


a-a = 0 = 0 × n [since 0 is multiple of n it is divisible by n]


⇒ a-a is divisible by n


⇒ (a,a) ∈ R


Thus, R is reflexive on Z.


R is Symmetric if (a,b)R(b,a)Ra,bZ


(a,b) ∈ R ⇒ (a-b) is divisible by n


⇒ (a-b) = nz for some z ∈ Z


⇒ -(b-a) = nz


⇒ b-a = n(-z) [∵ z ∈ Z ⇒ -z ∈ Z ]


⇒ (b-a) is divisible by n


⇒ (b,a) ∈ R


Thus, R is symmetric on Z.


R is Transitive if (a,b)R and (b,c)R(a,c)Ra,b,cZ


(a,b) ∈ R ⇒ (a-b) is divisible by n


⇒ a-b = nz1 for some z1∈ Z


(b,c) ∈ R ⇒ (b-c) is divisible by n


⇒ b-c = nz2 for some z2∈ Z


Now,


a-b = nz1 and b-c = nz2


⇒ (a-b) + (b-c) = nz1 + nz2


⇒ a-c = n(z1 + z2 ) = nz3 where z1 + z2 = z3


⇒ a-c = nz3 [∵ z1,z2 ∈ Z ⇒ z3∈ Z]


⇒ (a-c) is divisible by n.


⇒ (a, c) ∈ R


Thus, R is transitive on Z.


Since R is reflexive, symmetric and transitive it is an equivalence relation on Z.



Question 16.

If A = {1, 2, 3, 4 }, define relations on A which have properties of being:

(a) reflexive, transitive but not symmetric

(b) symmetric but neither reflexive nor transitive

(c) reflexive, symmetric and transitive.


Answer:

Given that, A = {1, 2, 3, 4 }


(a) Reflexive, transitive but not symmetric


Let R be a relation defined by


R = {(1,1),(1,2),(1,4),(2,2),(2,3),(3,2),(3,3),(4,2),(4,4)} on set A.


R is reflexive ∵ (1,1),(2,2),(3,3),(4,4) ∈ R


R is transitive ∵ (1,4) ∈ R and (4,2) ∈ R ⇒ (1,2) ∈ R


R is not symmetric ∵ (1,4) ∈ R but (4,1) ∉ R


Hence, R is reflexive, transitive but not symmetric.


(b) Symmetric but neither reflexive nor transitive


Let R be a relation defined by


R = {(1,2),(2,1),(2,3),(3,2)} on set A.


R is not reflexive ∵ (1,1),(2,2),(3,3),(4,4) ∉ R


R is symmetric ∵ (1,2) ∈ R ⇒ (2,1) ∈ R and (2,3) ∈ R ⇒ (3,2) ∈ R


R is not transitive ∵ (1,2) ∈ R and (2,1) ∈ R ⇒ (1,1) ∉ R


Hence, R is symmetric but neither reflexive nor transitive.


(c) Reflexive, symmetric and transitive.


Let R be a relation defined by


R = {(1,1),(1,2),(1,4),(2,1),(2,2),(2,3),(3,2),(3,3),(4,1),(4,4)} on set A.


R is reflexive ∵ (1,1),(2,2),(3,3),(4,4) ∈ R


R is symmetric ∵ (1,2),(1,4),(2,3) ∈ R ⇒ (2,1),(4,1),(3,2) ∈ R


R is transitive ∵ (1,2) ∈ R and (2,1) ∈ R ⇒ (1,1) ∈ R


Hence, R is reflexive, symmetric and transitive.



Question 17.

Let R be relation defined on the set of natural number N as follows:

R = {(x, y): x ∈N, y ∈N, 2x + y = 41}. Find the domain and range of the relation R. Also verify whether R is reflexive, symmetric and transitive.


Answer:

Given that, R = {(x, y): x ∈N, y ∈N, 2x + y = 41}


Now, 2x + y = 41


⇒ y = 41 - 2x (i)


Since x ∈N, y ∈N from (i) we get the relation


R = {(1,39),(2,37),(3,35),(4,33),(5,31),(6,29),(7,27),(8,25),


(9,23),(10,21),(11,19),(12,17),(13,15),(14,13),(15,11),


(16,9),(17,7),(18,5),(19,3),(20,1)}


Domain(R) ={1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20}


Range(R) ={1,3,5,7,9,11,13,15,17,19,21,23,25,27,29,31,33,35,


37,39}


R is not reflexive ∵ (1,1),(2,2)…(20,20) ∉ R


R is not symmetric ∵ (1,39) ∈ R but (39,1) ∉ R


R is not transitive ∵ (12,17),(17,7) ∈ R but (12,7) ∉ R


Hence, R is neither reflexive nor symmetric nor transitive.



Question 18.

Given A = {2, 3, 4}, B = {2, 5, 6, 7}. Construct an example of each of the following:

(a) an injective mapping from A to B

(b) a mapping from A to B which is not injective

(c) a mapping from B to A.


Answer:

Given that, A = {2, 3, 4}, B = {2, 5, 6, 7}


(a) an injective mapping from A to B


Let f : A → B denote a mapping f = {(x,y) : y=2x }


Now, y = 2x


When x=2 we get y = 4


Similarly, x=3 and 4 will give y=6 and 8 respectively.


∴ f = {(2,4),(3,6),(4,8)}


We observe that each element of A has unique image in B.


Thus, f is injective.


(b) a mapping from A to B which is not injective


Let g: A → B denote a mapping such that g = {(2,2),(3,5),(4,2)}


We observe that 2 and 4 ∈ A does not have unique image.


Thus, g is not injective.


(c) a mapping from B to A.


Let h : B → A denote a mapping such that


h = {(2,3),(5,2),(6,3),(7,4)}



Question 19.

Give an example of a map

which is one-one but not onto


Answer:

Let f : N → N, be a function given by f(x) = 2x.


In order to prove that f is one-one, it is sufficient to prove that f(x1)=f(x2) ⇒ x1=x2∀ x1, x2 ∈ N


Now, let f(x1) = f(x2)


⇒ 2x1= 2x2


⇒ x1= x2


⇒ f is one-one.


f is not onto, as for 1 ∈ N, there does not exist any x in N such that f(x) = 2x = 1.


Thus, f : N → N, be a function given by f(x) = 2x, which is one-one but not onto.



Question 20.

Give an example of a map

which is not one-one but onto


Answer:

Let f : N → N, be a function given by f(1) = f(2) = 1 and f(x) = x-1 for every x > 2.


Since, f(1) = 1 = f(2)


⇒ 1 and 2 does not have unique image.


Thus, f is not one-one.


Let f(x) = y


⇒ y = x-1


⇒ x = y+1


⇒ for each y ∈ R there exists x ∈ N such that f(x) = y.


Thus, f is onto.



Question 21.

Give an example of a map

which is neither one-one nor onto.


Answer:

Let the function f :R → R be defined by f (x) = cosx, ∀ x ∈ R.


We have,


f (x) = cosx, ∀ x ∈ R


In order to prove that f is one-one, it is sufficient to prove that f(x1)=f(x2) ⇒ x1=x2∀ x1, x2 ∈ A .


Let x1 = 0 and x2 = 2π are two different elements in R.


Now,


f(x1) = f(0) = cos0 = 1


f(x2) = f(2π) = cos2π = 1


we observe that f(x1)=f(x2) but x1 ≠ x2.


This shows that different element in R may have same image.


Thus, f(x) is not one-one.


We know that cosx lies between -1 and 1.


So, the range of f is [-1,1] which is not equal to its co-domain.


i.e., range of f ≠ R (co-domain)


In other words, range of f is less than co-domain, i.e there are elements in co-domain which does not have any pre-image in domain.


so, f is not onto.


Hence, f is neither one-one nor onto.



Question 22.

Let A = R – {3}, B = R – {1}. Let f : A → B be defined by ∀ x ∈ A . Then show that f is bijective.


Answer:

Given that,


In order to prove that f is one-one, it is sufficient to prove that f(x1)=f(x2) ⇒ x1=x2∀ x1, x2 ∈ A .


Let f(x1)=f(x2)



⇒ (x1-2)(x2-3) = (x2-2)(x1-3)


⇒ x1x2-3x1-2x2+6 = x1x2-3x2-2x1+6


⇒ -3x1-2x2 = -3x2-2x1


⇒ -3x1+2x1 = -3x2+2x2


⇒ (-3+2) x1 = (-3+2)x2


⇒ x1 = x2


∴ f is one-one.


f is onto if every element of B is the f-image of some element of A.


let f(x) = y



⇒ x-2 = y(x-3)


⇒ x-2 = xy-3y


⇒ x-xy = -3y+2


⇒ x(1-y) = -3y+2




Thus, for each y ∈ B there exists such that f(x) = y.


Hence, f is onto.


Since, f is one-one and onto therefore f is bijective.



Question 23.

Let A = [–1, 1]. Then, discuss whether the following functions defined on A are one-one, onto or bijective:



Answer:

Given that, A = [–1, 1]



Let f(x1) = f(x2)



⇒ 2x1 = 2x2


⇒ x1 = x2


⇒ f is one one


Now, let f(x) = y



⇒ 2y= x


⇒ for y=1 ∈ A we will have x = 2 ∉ A


⇒ f is not onto


Thus, f is one-one and not onto.



Question 24.

Let A = [–1, 1]. Then, discuss whether the following functions defined on A are one-one, onto or bijective:

g(x) = |x|


Answer:

(ii) Given that, A = [–1, 1]


let g(x1) = g(x2)


⇒ |x1|= |x2|


⇒ x1= ± x2


⇒ x1= x2 and x1= - x2


For e.g., g(-1) = |-1| = 1 and g(1) = |1| = 1


⇒ g is not one-one.


We observe that -1 does not have any pre-image in the domain since g(x) = |x| assumes only non-negative values.


i.e. we cannot find any number in domain which will give -1 in co-domain.


⇒ g is not onto


Hence, g is neither one one nor onto.



Question 25.

Let A = [–1, 1]. Then, discuss whether the following functions defined on A are one-one, onto or bijective:

h(x) = x |x|


Answer:

Given that, A = [–1, 1]


let h(x1) = h(x2)


⇒ x1|x1|= x2|x2|


if x1,x2 >0


⇒ x12 = x22


⇒ x1= x2


if x1,x2 < 0


⇒ x12 = x22


⇒ x1= x2


⇒ h is one-one.


Let h(x) = y


⇒ y = x |x|


⇒ y = x2


Thus, for each y co domain there exists x in domain.


⇒ h is onto.


Hence, h is one one and onto.


So, h is bijective.



Question 26.

Let A = [–1, 1]. Then, discuss whether the following functions defined on A are one-one, onto or bijective:

k(x) = x2


Answer:

(iv) Given that, A = [–1, 1]


let k(x1) = k(x2)


⇒ x12= x22


⇒ x1= ± x2


⇒ x1= x2 and x1= - x2


For e.g., k(-1) = |-1| = 1 and k(1) = |1| = 1


⇒ k is not one-one.


We observe that -1 does not have any pre-image in the domain since k(x) = x2 assumes only non-negative values.


i.e. we cannot find any number in domain which will give -1 in co-domain.


⇒ k is not onto


⇒ Hence, k is neither one one nor onto.



Question 27.

Each of the following defines a relation on N:

x is greater than y, x, y ∈N

Determine which of the above relations are reflexive, symmetric and transitive.


Answer:

Let R = {(x,y): x is greater than y ∀ x,y ∈ N } be a relation defined on N.


Now,


We observe that, any element x ∈ N cannot be greater than itself.


⇒ (x,x) ∉ R ∀ x ∈ N


⇒ R is not reflexive.


Let (x,y) ∈ R ∀ x, y ∈ N


⇒ x is greater than y


But y cannot be greater than x if x is greater than y.


⇒ (y,x) ∉ R


For e.g., we observe that (5,2) ∈ R i.e 5 > 2 but 2 ≯ 5 ⇒ (2,5) ∉ R


⇒ R is not symmetric


Let (x,y) ∈ R and (y,z) ∈ R ∀ x, y,z ∈ N


⇒ x > y and y > z


⇒ x > z


⇒ (x,z) ∈ R


For e.g., we observe that


(5,4) ∈ R ⇒ 5 > 4 and (4,3) ∈ R ⇒ 4 > 3


And we know that 5 > 3 ∴ (5,3) ∈ R


⇒ R is transitive.


Thus, R is transitive but not reflexive not symmetric.



Question 28.

Each of the following defines a relation on N:

x + y = 10, x, y ∈N

Determine which of the above relations are reflexive, symmetric and transitive.


Answer:

Let R = {(x,y): x + y =10, ∀ x,y ∈ N } be a relation defined on N.


R = {(1,9),(2,8),(3,7),(4,6),(5,5),(6,4),(7,3),(8,2),(9,1)}


Now,


R is not reflexive ∵ (2,2) ∉ R.


R is symmetric ∵ (3,7) ∈ R ⇒ (7,3) ∈ R


R is not transitive ∵ (1,9) ∈ R and (9,1) ∈ R but (1,1) ∉ R.


Thus, R is symmetric but not reflexive not transitive.



Question 29.

Each of the following defines a relation on N:

x y is square of an integer x, y ∈N

Determine which of the above relations are reflexive, symmetric and transitive.


Answer:

Let R = {(x,y): x y is square of an integer, ∀ x,y ∈ N } be a relation defined on N.


R is reflexive ∵ x2 is square of an integer ∀ x ∈ N ⇒ (x,x) ∈ R


Let (x,y) ∈ R ∀ x, y ∈ N


⇒ x y is square of an integer


⇒ y x is square of an integer


⇒ (y,x) ∈ R


⇒ R is symmetric


Let (x,y) ∈ R and (y,z) ∈ R ∀ x, y,z ∈ N


⇒ x y is square of an integer and yz is square of an integer


let xy = p2 and yz = q2 for some p,q ∈ Z



, which is square of an integer


⇒ (x,z) ∈ R


⇒ R is transitive.


Thus, R is reflexive, symmetric and transitive.



Question 30.

Each of the following defines a relation on N:

x + 4y = 10 x, y ∈N.

Determine which of the above relations are reflexive, symmetric and transitive.


Answer:

Let R = {(x,y): x + 4y =10, ∀ x,y ∈ N } be a relation defined on N.


R = {(2,2),(6,1)}


Now,


R is not reflexive ∵ (1,1) ∉ R.


R is not symmetric ∵ (6,1) ∈ R but (1,5) ∉ R


R is not transitive


∵ (x,y) ∈ R ⇒ x+4y=10 and (y,z) ∈ R ⇒ y+4z=10


⇒ x-16z = -30


⇒ (x,z) ∉ R


Thus, R is neither symmetric nor reflexive nor transitive.



Question 31.

Let A = {1, 2, 3, ... 9} and R be the relation in A ×A defined by (a, b) R (c, d) if a + d = b + c for (a, b), (c, d) in A ×A. Prove that R is an equivalence relation and also obtain the equivalent class [(2, 5)].


Answer:

Given that, A = {1, 2, 3, ... 9} and R be the relation in A ×A defined by (a, b) R (c, d) if a + d = b + c for (a, b), (c, d) in A ×A.


Let (a,b) R (a,b)


⇒ a+b = b+a


which is true since addition is commutative on N.


⇒ R is reflexive.


Let (a,b) R (c,d)


⇒ a+d = b+c


⇒ b+c = a+d


⇒ c+b = d+a [since addition is commutative on N]


⇒ (c,d) R (a,b)


⇒ R is symmetric.


Let (a,b) R (c,d) and (c,d) R (e,f)


⇒ a+d = b+c and c+f = d+e


⇒ (a+d) – (d+e) = (b+c ) – (c+f)


⇒ a-e= b-f


⇒ a+f = b+e


⇒ (a,b) R (e,f)


⇒ R is transitive.


Hence, R is an equivalence relation.


The equivalence class [(2,5)] = {(1,4),(2,5),(3,6),(4,7),(5,8),(6,9)}



Question 32.

Using the definition, prove that the function f : A → B is invertible if and only if f is both one-one and onto.


Answer:

f : A → B is one-one if the images of distinct elements of A under f are distinct, i.e.,for every a, b ∈ A, f(a) = f(b)⇒ a = b


we suppose that f : A → B is not one-one function.


Let f(a) = x and f(b) = x


⇒ f-1(x) = a and f-1(x) = b


⇒ inverse function cannot be defined as we have two images ‘a’ and ‘b’ for one pre-image ‘x’.


So, f can be invertible if it is one-one.


Now, suppose that f : A → B is not onto function.


Let B = {x,y,z} and range of f = {x,y}


We can observe that ‘z’ does not have any pre-image in A.


But f-1 has z as a pre-image which does not have any image in A.


So, f can be invertible if it is onto.


Hence, f is invertible if and only if it is both one-one and onto.



Question 33.

Functions f, g : R → R are defined, respectively, by f (x) = x2 + 3x + 1, g (x) = 2x – 3, find

(i) f o g (ii) g o f (iii) f o f (iv) g o g


Answer:

Given that, f (x) = x2 + 3x + 1, g (x) = 2x – 3


(i) f o g


fog = f(g(x)) = f(2x-3)


= (2x-3)2 + 3(2x-3) + 1


= (4x2-12x+9) + 6x – 9 +1


= 4x2 - 6x + 1


∴ fog = 4x2 - 6x + 1


(ii) g o f


gof = g(f(x)) = g(x2 + 3x + 1)


= 2(x2 + 3x + 1) – 3


= 2x2 + 6x + 2 – 3


= 2x2 + 6x – 1


∴ gof = 2x2 + 6x – 1


(iii) f o f


fof = f(f(x)) = f(x2 + 3x + 1)


= (x2 + 3x + 1)2 + 3(x2 + 3x + 1) + 1


= x4+9x2+1+6x3+6x+2x2+3x2+9x+3+1


= x4+6x3+14x2+15x+5


∴ fof = x4+6x3+14x2+15x+5


(iv) g o g


gog = g(g(x)) = g(2x-3)


= 2(2x-3) – 3


= 4x-6-3


= 4x-9


∴ gog = 4x-9



Question 34.

Let * be the binary operation defined on Q. Find which of the following binary operations are commutative

(i) a * b = a – b ∀ a, b ∈Q

(ii) a * b = a2 + b2∀ a, b ∈Q

(iii) a * b = a + ab ∀ a, b ∈Q

(iv) a * b = (a – b)2∀ a, b ∈Q


Answer:

Given that, * be the binary operation defined on Q.


A binary operation ‘*’ is commutative if a*b = b*aa, bQ


(i) a * b = a – b ∀ a, b ∈Q


a * b = a – b = -b+a = -(b-a) = -(b*a)


∴ a*b ≠ b*a


Hence, ‘*’ is not commutative on Q.


(ii) a * b = a2 + b2 ∀ a, b ∈Q


a * b = a2 + b2


= b2 + a2 [∵ addition is commutative on Q ⇒ a+b = b+a ]


= b*a


∴ a*b = b*a


Hence, ‘*’ is commutative on Q.


(iii) a * b = a + ab ∀ a, b ∈ Q


a * b = a + ab and b*a = b + ab


⇒ a + ab ≠ b + ab


∴ a*b ≠ b*a


Hence, ‘*’ is not commutative on Q.


(iv) a * b = (a – b)2 ∀ a, b ∈Q


a * b = (a – b)2 = {-(b-a)}2


= (b-a)2


=b*a


∴ a*b = b*a


Hence, ‘*’ is commutative on Q.



Question 35.

Let * be binary operation defined on R by a * b = 1 + ab, ∀a, b ∈R. Then the operation * is

(i) commutative but not associative

(ii) associative but not commutative

(iii) neither commutative nor associative

(iv) both commutative and associative


Answer:

Given that,


‘*’ be binary operation defined on R by a * b = 1 + ab, ∀ a, b ∈ R


A binary operation ‘*’ is commutative if a*b = b*aa, bR


Now,


a*b = 1+ab = 1+ba [∵ ab=ba since multiplication is commutative


on R]


⇒ 1+ba = b*a


∴ a*b = b*a ∀ a, b ∈ R


So, ‘*’ is commutative on R.


A binary operation ‘*’ is associative if (a*b)*c = a*(b*c)a, b,cR


Now,


(a*b)*c = (1+ab)*c = 1+(1+ab)c = 1+c+abc


a*(b*c) = a*(1+bc) = 1+a(1+bc) = 1+a+abc


∴ (a*b)*c ≠ a*(b*c)


So, ‘*’ is not associative on R.


Hence, ‘*’ is commutative but not associative on R.



Question 36.

Let T be the set of all triangles in the Euclidean plane, and let a relation R on T be defined as aRb if a is congruent to b ∀a, b ∈T. Then R is
A. reflexive but not transitive

B. transitive but not symmetric

C. equivalence

D. none of these


Answer:

Given that,


R be a relation on T defined as aRb if a is congruent to b ∀ a, b ∈ T


Now,


aRa ⇒ a is congruent to a, which is true since every triangle is congruent to itself.


⇒ (a,a) ∈ R ∀ a ∈ T


⇒ R is reflexive.


Let aRb ⇒ a is congruent to b


⇒ b is congruent to a


⇒ bRa


∴ (a,b) ∈ R ⇒ (b,a) ∈ R ∀ a, b ∈ T


⇒ R is symmetric.


Let aRb ⇒ a is congruent to b and bRc ⇒ b is congruent to c


⇒ a is congruent to c


⇒ aRc


∴ (a,b) ∈ R and (b,c) ∈ R ⇒ (a,c) ∈ R ∀ a, b,c ∈ T


⇒ R is transitive.


Hence, R is an equivalence relation.


Question 37.

Consider the non-empty set consisting of children in a family and a relation R defined as aRb if a is brother of b. Then R is
A. symmetric but not transitive

B. transitive but not symmetric

C. neither symmetric nor transitive

D. both symmetric and transitive


Answer:

Given that, relation R is defined as aRb if a is brother of b


Now,


aRa ⇒ a is brother of a, which is not true.


⇒ (a,a) ∉ R


⇒ R is not reflexive


aRb ⇒ a is brother of b but this does not mean that b is brother of a,b can be sister of a.


Thus, (a,b) ∈ R ⇒ (b,a) ∉ R


⇒ R is not symmetric.


aRb ⇒ a is brother of b and bRc ⇒ b is brother of c


⇒ a is a brother of c.


⇒ R is transitive.


Hence, R is transitive but not symmetric.


Question 38.

The maximum number of equivalence relations on the set A = {1, 2, 3} are
A. 1

B. 2

C. 3

D. 5


Answer:

An equivalence relation is one which is reflexive, symmetric and transitive.


Given that, A = {1, 2, 3}


We can define equivalence relation on A as follows.


R1 = A × A = {(1,1),(1,2),(1,3),(2,1),(2,2),(2,3),


(3,1),(3,2),(3,3)}


R1 is reflexive ∵ (1,1),(2,2),(3,3) ∈ R


R1 is symmetric ∵ (1,2),(1,3),(2,3) ∈ R ⇒ (2,1),(3,1),(3,2) ∈ R


R1 is Transitive ∵ (1,2) ∈ R and (2,3) ∈ R ⇒ (1,3) ∈ R


Similarly,


R2 = {(1,1),(2,2),(3,3),(1,2),(2,1)}


R3 = {(1,1),(2,2),(3,3),(1,3),(3,1)}


R4 = {(1,1),(2,2),(3,3),(2,3),(3,2)}


R5 = {(1,1),(2,2),(3,3)}


∴ maximum number of equivalence relation on A is ‘5’.


Question 39.

If a relation R on the set {1, 2, 3} be defined by R = {(1, 2)}, then R is
A. reflexive

B. transitive

C. symmetric

D. none of these


Answer:

Given that, R on the set {1, 2, 3} be defined by R = {(1, 2)}


Now,


R is not reflexive ∵ (1,1),(2,2),(3,3) ∉ R


R is not symmetric ∵ (1,2)∈ R but (2,1) ∉ R


R is not transitive ∵ R has only one ordered pair.


Thus, R is neither reflexive nor transitive nor symmetric.


Hence, option ‘D’ is corect.


Question 40.

Let us define a relation R in R as aRb if a ≥ b. Then R is
A. an equivalence relation

B. reflexive, transitive but not symmetric

C. symmetric, transitive but

D. neither transitive nor reflexive not reflexive but symmetric.


Answer:

Given that, aRb if a ≥ b


Now,


We observe that, a ≥ a since every a ∈ R is greater than or equal to itself.


⇒ a ≥ a ⇒ (a,a) ∈ R ∀ a ∈ R


⇒ R is reflexive.


Let (a,b) ∈ R


⇒ a ≥ b


But b cannot be greater than a if a is greater than b.


⇒ (b,a) ∉ R


For e.g., we observe that (5,2) ∈ R i.e 5 ≥ 2 but 2 ≱ 5 ⇒ (2,5) ∉ R


⇒ R is not symmetric


Let (a,b) ∈ R and (b,c) ∈ R


⇒ a ≥ b and b ≥ c


⇒ a ≥ c


⇒ (a,c) ∈ R


For e.g., we observe that


(5,4) ∈ R ⇒ 5 ≥ 4 and (4,3) ∈ R ⇒ 4 ≥ 3


And we know that 5 ≥ 3 ∴ (5,3) ∈ R


⇒ R is transitive.


Thus, R is reflexive, transitive but not symmetric.


Question 41.

Let A = {1, 2, 3} and consider the relation

R = {1, 1), (2, 2), (3, 3), (1, 2), (2, 3), (1,3)}.

Then R is
A. reflexive but not symmetric

B. reflexive but not transitive

C. symmetric and transitive

D. neither symmetric, nor transitive


Answer:

Given that, A = {1, 2, 3} and


R = {1, 1), (2, 2), (3, 3), (1, 2), (2, 3), (1,3)}.


Now,


R is reflexive ∵ (1,1),(2,2),(3,3) ∈ R


R is not symmetric ∵ (1,2),(2,3),(1,3) ∈ R but (2,1),(3,2),(3,1) ∉ R


R is transitive ∵ (1,2) ∈ R and (2,3) ∈ R ⇒ (1,3) ∈ R


Thus, R is reflexive, transitive but not symmetric.


Hence, option ‘A’ is correct.


Question 42.

The identity element for the binary operation * defined on Q ~ {0} asb ∈Q ~ {0}is
A. 1

B. 0

C. 2

D. none of these


Answer:

Given that,


Let e be the identity element for * such that


a*e = e*a = a


Now,



⇒ 2a = ae


⇒ e = 2


Question 43.

If the set A contains 5 elements and the set B contains 6 elements, then the number of one-one and onto mappings from A to B is
A. 720

B. 120

C. 0

D. none of these


Answer:

Number of elements in A = 5


Number of elements in B = 6


Now, for a function to be one-one all elements of domain should have unique image in co-domain.


Here, 5 elements of A can be mapped to 5 distinct element of B.


⇒ function is one-one


But range of B is 6 that means there is one element in B which does not have pre-image in A.


Thus the function cannot be onto if it is one-one.


Also, if all 6 elements of B are mapped to all 5 elements of A, then we can observe there will be atleast 2 elements of B which have same pre-image in A.


⇒ one element of A will have two image in B.


⇒ function is not one-one


Thus the function cannot be one-one if it is onto.


Hence, there cannot be any one-one and onto mapping from A to B.


Question 44.

Let A = {1, 2, 3, ...n} and B = {a, b}. Then the number of surjections from A into B is
A. nP2

B. 2n – 2

C. 2n – 1

D. None of these


Answer:

Given that, A = {1, 2, 3, ...n} and B = {a, b}


Number of elements in A = n


Number of elements in B = 2


No. of possible function from A → B is n2 (i.e. number of possible ways n elements of A can be mapped to 2 elements of B.


Now, not all of these functions are surjective.


we know that function f : A → B is surjective if both the elements of B are mapped.


Out of these n2 functions there will be two functions where all the elements of A are mapped to first element of B and where all the elements of A are mapped to second element of B, those functions are not surjective.


⇒ number of surjective functions from A → B are n2 – 2.


Question 45.

Let f :R → R be defined byThen f is
A. one-one

B. onto

C. bijective

D. f is not defined


Answer:

Given that,


If x=0 then


Thus, f is not defined.


Question 46.

Let f :R → R be defined by f (x) = 3x2 – 5 and g : R → R by. Then g o f is
A.

B.

C.

D.


Answer:

Given that, f (x) = 3x2 – 5 and


Now,


gof(x) = g(f(x))


= g(3x2-5)


=


=


=


Question 47.

Which of the following functions from Z into Z are bijections?
A. f (x) = x3

B. f (x) = x + 2

C. f (x) = 2x + 1

D. f (x) = x2 + 1


Answer:

A function is bijective iff it is one-one and onto.


Option A. f (x) = x3


Let f(x1) = f(x2)


⇒ x13= x23


⇒ x1= x2


⇒ f is one one


Let f(x) = y, y ∈ Z


⇒ y = x3


⇒ x = y1/3 but y1/3∉ Z


⇒ f is not onto


Thus, f is not bijective.


Option B. f (x) = x + 2


Let f(x1) = f(x2)


⇒ x1+2 = x2+2


⇒ x1= x2


⇒ f is one one


Let f(x) = y, y ∈ Z


⇒ y = x + 2


⇒ x = y – 2


⇒ for each y ∈ Z there exists x ∈ Z (domain) such that f(x) = y.


⇒ f is onto


Thus, f is bijective.


Option C. f (x) = 2x + 1


Let f(x1) = f(x2)


⇒ 2x1+1 = 2x2+1


⇒ x1= x2


⇒ f is one one


Let f(x) = y, y ∈ Z


⇒ y = 2x + 1


⇒ y - 1 = 2x



We observe that if we put y=0, then .


Thus, y = 0 ∈ Z does not have pre image in Z (domain)


⇒ f is not onto.


Thus, f is not bijective.


Option D. f (x) = x2 + 1


let f(x1) = f(x2)


⇒ x12 + 1 = x22 + 1


⇒ x12 = x22


⇒ x1 = ± x2


⇒ x1= x2 and x1= - x2


For e.g., f(-1) = |-1| = 1 and f(1) = |1| = 1


⇒ f is not one-one.


Since, f is not one one it cannot be bijective.


Question 48.

Let f :R → R be the functions defined by f (x) = x3 + 5. Then f–1 (x) is
A.

B.

C.

D. 5 – x


Answer:

Given that, f(x) = x3 + 5


Let f(x) = y


⇒ y = x3 + 5


⇒ y – 5 = x3


⇒ x3 = y – 5



[∵ f(x) = y, ⇒ x = f-1(y)]



Question 49.

Let f : A → B and g : B → C be the bijective functions. Then (g o f)–1 is
A. f–1 o g–1

B. f o g

C. g–1 o f–1

D. g o f


Answer:

Given that, f : A → B and g : B → C be the bijective functions.


Let A = {1,3,4}, B ={2,5,1} and C = {3,1,2}


f : A → B is bijective function.


∴ f = {(1, 2), (3, 5), (4, 1)


f-1 = {(2,1),(5,3),(1,4)}


g : B → C is bijective function.


∴ g = {(2, 3), (5, 1), (1, 4)}


g-1 ={(3,2),(1,5),(4,1)}


Now,


gof (1) = g(f(1)) = g(2) = 3


gof (3) = g(f(3)) = g(5) = 1


gof (4) = g(f(4)) = g(1) = 4


∴ gof = {(1,3),(3,1),(4,4)} (1)


(gof)-1 = {(3,1),(1,3),(4,4)} (2)


fog (2) = f(g(2)) = f(3) = 5


fog (5) = f(g(5)) = f(1) = 2


fog (1) = f(g(1)) = f(4) = 1


∴ fog = {(2,5),(5,2),(1,1)} (3)


(fog)-1 = {(5,2),(2,5),(1,1)} (4)


f-1og-1 (3) = f-1(g-1(3)) = f-1(2) = 1


f-1og-1 (1) = f-1(g-1(1)) = f-1(5) = 3


f-1og-1 (4) = f-1(g-1(4)) = f-1(1) = 4


∴ f-1og-1 = {(3,1),(1,3),(4,4)} (5)


g-1of-1 (2) = g-1(f-1(2)) = g-1(1) = 5


g-1of-1 (5) = g-1(f-1(5)) = g-1(3) = 2


g-1of-1 (1) = g-1(f-1(1)) = g-1(4) = 1


∴ g-1of-1 = {(2,5),(5,2),(1,1)} (6)


On comparing 1,2,3,4,5 and 6 we observe that 2 and 5 are same.


i.e (g o f)–1 = f-1og-1


Question 50.

Let be defined by. Then
A. f–1 (x) = f (x)

B. f–1 (x) = – f (x)

C. (f o f) x = – x

D.


Answer:

Given that,


Let f(x) = y



⇒ (5x-3)y = 3x+2


⇒ 5xy-3y = 3x+2


⇒ 5xy–3x = 2+3y


⇒ (5y-3)x = 2+3y



[∵ f(x) = y, ⇒ x = f-1(y)]



⇒ f-1(x) = f(x)


Question 51.

Let f : [0, 1] → [0, 1] be defined by

Then (f o f) x is
A. constant

B. 1 + x

C. x

D. none of these


Answer:

Given that, f : [0, 1] → [0, 1] be defined by


Now,


(fof)(x) =


=


=


∴ (fof)(x) = x


Question 52.

Let f : [2, ∞) → R be the function defined by f (x) = x2–4x+5, then the range of f is
A. R

B. [1, ∞)

C. [4, ∞)

D. [5, ∞)


Answer:

Given that, f (x) = x2–4x+5


Let f(x) = y


⇒ y = x2–4x+5


⇒ y = x2–4x+4+1


⇒ y = (x-2)2+1


⇒ y-1 = (x-2)2


⇒ (x-2)2= y-1




Now, if f is real valued function then


⇒ y-1 ≥ 0


⇒ y ≥ 1


∴ the range of f is [1, ∞).


Question 53.

Let f : N → R be the function defined byand g : Q → R be another function defined by g (x) = x + 2. Then (g o f)3/2 is
A. 1

B. 1

C. 7/2

D. None of these


Answer:

Given that, and g (x) = x + 2


Now,


gof(x) = g(f(x))



⇒ 1+2 = 3


Question 54.

Let f :R → R be defined by



Then f (– 1) + f (2) + f (4) is
A. 9

B. 14

C. 5

D. none of these


Answer:

Given that,



Now,


f(-1) = 3(-1) = -3 [since -1<1 and f(x) = 3x for x≤ 1]


f(2) = 22 = 4 [since 2<3 and f(x) = x2 for 1<x≤ 3]


f(4) = 2(4) = 8 [since 4>3 and f(x) = 2x for x>3]


∴ f (– 1) + f (2) + f (4) = -3+4+8 = 9


Question 55.

Let f :R → R be given by f (x) = tan x. Then f–1 (1) is
A. π/4

B.

C. does not exist

D. none of these


Answer:

Given that, f (x) = tan x


Let f(x) = y


⇒ y = tanx


⇒ x = tan-1y


⇒ f-1(y) = tan-1y [∵ f(x) = y ⇒ x = f-1(y) ]


⇒ f-1(x) = tan-1x


⇒ f-1(1) = tan-11




Question 56.

Fill in the blanks in each of the

Let the relation R be defined in N by aRb if 2a + 3b = 30. Then R = ______.


Answer:

Given that, 2a + 3b = 30


⇒ 3b = 30 - 2a



Since a,b ∈ N, ‘a’ must be a multiple of 3.


Substituting a = 3 in above equation we get,



∴ for a = 3, b = 8


Similarly,


For a = 6, b = 6


For a = 9, b = 4


For a = 12,b = 2


Thus, R = {(3,8),(6,6),(9,4),(12,2)}



Question 57.

Fill in the blanks in each of the

Let the relation R be defined on the set

A = {1, 2, 3, 4, 5} by R = {(a, b) : |a2 – b2| < 8}. Then R is given by _______.


Answer:

Given that, A = {1, 2, 3, 4, 5} and R = {(a, b) : |a2 – b2| < 8}


Let us check the relation for a=1,b=2


⇒ |12 – 22| = |-3|= 3 < 8


⇒ (1,2) ∈ R


Similarly, we can check for all the ordered pairs of (a,b) which satisfies the relation.


Hence, R = {(1,1),(1,2),(2,1),(2,2),(2,3),(3,2),(3,3),(3,4),(4,3),


(4,4),(5,5)}



Question 58.

Fill in the blanks in each of the

Let f = {(1, 2), (3, 5), (4, 1) and g = {(2, 3), (5, 1), (1, 3)}. Then g o f = ______and f o g = ______.


Answer:

Given that,


f = {(1, 2), (3, 5), (4, 1) and g = {(2, 3), (5, 1), (1, 3)}


Now,


gof (1) = g(f(1)) = g(2) = 3


gof (3) = g(f(3)) = g(5) = 1


gof (4) = g(f(4)) = g(1) = 3


∴ gof = {(1,3),(3,1),(4,3)}


fog (2) = f(g(2)) = f(3) = 5


fog (5) = f(g(5)) = f(1) = 2


fog (1) = f(g(1)) = f(3) = 5


∴ fog = {(2,5),(5,2),(1,5)}



Question 59.

Fill in the blanks in each of the

Let f :R → R be defined by. Then (f o f o f) (x) = _______


Answer:

Given that,


Now, (fofof)(x) = f[f(f(x))]


=


=


=


=


=


=


=


=


∴ (f o f o f) (x) =



Question 60.

Fill in the blanks in each of the

If f (x) = {4 – (x–7)3}, then f–1(x) = _______.


Answer:

Given that, f (x) = {4 – (x–7)3}


Let f(x) = y,


⇒ y = {4 – (x–7)3}


⇒ y – 4 = – (x–7)3


⇒ 4 – y = (x–7)3


⇒ (x–7)3 = 4 – y




[∵ f(x) = y, ⇒ x = f-1(y)]




Question 61.

State True or False for the statements

Let R = {(3, 1), (1, 3), (3, 3)} be a relation defined on the set A = {1, 2, 3}. Then R is symmetric, transitive but not reflexive.


Answer:

False

Given that, R = {(3, 1), (1, 3), (3, 3)} be a relation defined on the set A = {1, 2, 3}


Now,


R is not reflexive ∵ (1,1),(2,2) ∉ R.


R is symmetric ∵ (3,1) ∈ R ⇒ (1,3) ∈ R


R is not transitive ∵ (1,3) ∈ R and (3,1) ∈ R but (1,1) ∉ R.



Question 62.

State True or False for the statements

Let f : R → R be the function defined by f (x) = sin (3x+2)∀x ∈R. Then f is invertible.


Answer:

False

Given that, f : R → R be the function defined by


f (x) = sin (3x+2) ∀ x ∈R


f is invertible if it is bijective that is f should be one-one and onto.


Now, we know that sin x lies between -1 and 1.


So, the range of f(x) = sin (3x+2) is [-1,1] which is not equal to its co-domain.


i.e., range of f ≠ R (co-domain)


In other words, range of f is less than co-domain, i.e there are elements in co-domain which does not have any pre-image in domain.


so, f is not onto.


Hence, f is not invertible.



Question 63.

State True or False for the statements

Every relation which is symmetric and transitive is also reflexive.


Answer:

False

Let R = {(1, 1), (1, 2), (2, 1), (3, 3)} be a relation defined on set A= {1,2,3}


Now,


R is not reflexive ∵ (2,2) ∉ R.


R is symmetric ∵ (1,2) ∈ R ⇒ (2,1) ∈ R


R is transitive ∵ (1,2) ∈ R and (2,1) ∈ R ⇒ (1,1) ∈ R.


Thus, It is not true that every relation which is symmetric and transitive is also reflexive.



Question 64.

State True or False for the statements

An integer m is said to be related to another integer n if m is a integral multiple of n. This relation in Z is reflexive, symmetric and transitive.


Answer:

False

Let R be the relation defined on Z by mRn if m is a integral multiple of n.


Let mRm ∈ R


⇒ m is a integral multiple of m.


Which is true since m is integral multiple of itself.


Thus, R is reflexive.


Let mRn ∈ R


⇒ m is a integral multiple of n


⇒ m= zn ∀ z ∈ Z



Since,


⇒ n is not integral multiple of m.


⇒ nRm ∉ R


Thus, R is not symmetric.


Let mRn ∈ R and nRp ∈ R


⇒ m is a integral multiple of n and n is a integral multiple of p


⇒ m is a integral multiple of p


⇒ mRp ∈ R


Thus, R is transitive.


Hence, the given statement is false.



Question 65.

State True or False for the statements

Let A = {0, 1} and N be the set of natural numbers. Then the mapping f :N → A defined by f (2n–1) = 0, f (2n) = 1,∀n ∈N, is onto.


Answer:

True

Given that, f :N → A defined by f (2n–1) = 0, f (2n) = 1,∀n ∈N,


We observe that for each element of A(co-domain) there exist a pre image in N(domain).


For 0 ∈ A there exist (2n-1),∀ n ∈N


For 1 ∈ A there exist (2n),∀ n ∈N


Thus, the mapping is onto.



Question 66.

State True or False for the statements

The relation R on the set A = {1, 2, 3} defined as R = {{1, 1), (1, 2), (2, 1), (3, 3)}is reflexive, symmetric and transitive.


Answer:

False

Given that, A = {1, 2, 3} and R = {(1, 1), (1, 2), (2, 1), (3, 3)}


Now,


R is not reflexive ∵ (2,2) ∉ R



Question 67.

State True or False for the statements

The composition of functions is commutative.


Answer:

False

In order to prove composition of functions is commutative we need to show


(fog)(x) = (gof)(x)


Let us suppose, f(x) = 2x, g(x) = 1 + x2


Now,


(fog)(x) = f(g(x)) = f(1+x2)


= 2(1+x2) = 2+2x2 (i)


(gof)(x) = g(f(x)) = g(2x)


= 1+(2x)2 = 1+4x2 (ii)


From (i) and (ii), we observe that


(fog)(x) ≠ (gof)(x)


Thus, composition of functions is not commutative.



Question 68.

State True or False for the statements

The composition of functions is associative.


Answer:

True

In order to prove composition of functions is associative we need to show


[fo(goh)](x) = [(fog)oh](x)


Let us suppose, f(x) = x, g(x) = 2x, h(x) = x + 2


Now,


[fo(goh)](x) = f(g(h(x))) = f(g(x+2)) [∵ h(x) = x + 2 ]


= f(2(x+2)) = f(2x+4)


= 2x+4 (i)


[(fog)oh](x) = (fog)oh(x) = (fog)(h(x))


= (fog)(x+2) = f(g(x+2))


= f(2(x+2)) = f(2x+4)


= 2x+4 (ii)


From (i) and (ii), we observe that


[fo(goh)](x) = [(fog)oh](x)


Thus, composition of functions is associative.



Question 69.

State True or False for the statements

Every function is invertible.


Answer:

False

A function is invertible if and only if it is one-one and onto. Hence, only bijective functions are invertible.



Question 70.

State True or False for the statements

A binary operation on a set has always the identity element.


Answer:

False

We know that, ‘e’ is called an identity element for the binary operation ‘*’ on set S, such that


a * e = e * a = a ∀ a ∈ S


Let ‘+’ be a binary operation on set N.


Now, we need to find e ∈ N such that


n + e = e + n = n ∀ n ∈ N


n + 0 = 0 + n = n ∀ n ∈ N


We observe that addition of any natural number with 0 gives the desired result but 0 ∉ N, hence 0 is not the identity element for the addition operation on N.


∴ The binary operation ‘+’ on N does not have any identity element.