DHARM
16 MATHEMATICAL FOUNDATION OF COMPUTER SCIENCE
Thus,
- | f : X → Y | = 27, when f is arbitrary.
- For surjective mapping img (f) = {a, b, c}. So, we have the last column and ‘abc’
gives the | f : X → Y | = 6. - Since, the last column together with ‘abc’ gives that each element of X has a unique
image in Y hence, | f : X → Y | = 6. - The last column together with ‘abc’ gives the bijective mapping, so | f : X → Y | = 6.
- The monotone mapping are those in the first two columns, so | f : X → Y | = 10.
- The antitone mapping are found in the columns three, four, fifth, and six are
| f : X → Y | = 2 + 3 + 0 + 1 = 6.
1.5.2 Composition of Functions....................................................................................
Given two function f : X → Y and g : Y → Z, then g ◊ f is called composite function, where,
g ◊ f = g(f(x)) = {(x, z)/x ∈ X and z ∈ Z and (y = f(x) and z = g(y)) for any y ∈ Y}.
Therefore, the necessary condition for g ◊ f is, img (f) ⊆ arg (g), Otherwise g ◊ f = ∅.
Conversely, f ◊ g may or may not exist. It exists if and only if img (g) ⊆ arg (f).
Example 1.7. Let f : R → R; f(x) = – x^2 and g : R+ → R+; g(x) = x where R is the set of real
numbers and R+ is the set of positive real numbers. Determine f ◊ g and g ◊ f.
Sol. We have mapping f =
...... , , , , , ...
...... , , , , , ...
−−
−−
F
H
I
K
21012
41014 and g =
012
012
, , , ......
, , ,......
F
HG
I
KJ
To determine f ◊ g we must have img (g) ⊆ arg (f), because R+ ⊆ R.
Since, f ◊ g = f(g(x)) = f( x) = – ( x)^2 = – x.
Therefore, f ◊ g = {(x, – x)/x ∈ R};
Similarly to determine g ◊ f; since img (f) ⊆/ arg (f) because img (f) ∈ R and arg (g) ∈ R+ so R
⊆/ R+. Hence, g ◊ f does not exist.
Example 1.8. Let a function f : R → R, where f(x) = x^3 – 2 and R is the set of real numbers , find
f–1. Also show that f ◊ f–1 = I.
Sol. Given mapping is represented by the expression, i.e.
f =
... ...
... ...
x
x^3 − (^2) x
F
H
I
K ∈R ⇒ f =
... , , , , ...
... , , , , ...
−−
− −−−
F
H
I
K
21012
10 3 2 1 6
Since f : R → R is surjective, so f –1 exists, i.e.
f –1: R → R
Since, f(x) = x^3 – 2 = y (assume); then f –1 (y) = x.
⇒ x = (y + 2)1/3
⇒ y = (x + 2)1/3 [replace x and y]
Therefore, inverse of f(x) is (x + 2)1/3.
Let (x + 2)1/3 = g(x),
So, f ◊ f–1 = f ◊ g = f(g(x))
= f((x + 2)1/3)
= ((x + 2)1/3)^3 – 2;