10th Maths Chapter 1
Relations and Functions
Exercise 1.5
10th Maths Chapter 1 Relations and Functions Exercise 1.4, 10th Maths Chapter 1 Relations and Functions Exercise 1.5
Tamilnadu Samacheer Kalvi 10th Maths Solutions Chapter 1 Relations and Functions Ex 1.5
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10th Maths Chapter 1 video classes
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Class 10 Chapter 1 All Exercise Sums
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Class 10 Chapter 1 Example 1.1 to 1.5
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Class 10 Chapter 1 Example 1.6 to 1.10
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Class 10 Chapter 1 Example 1.11 to 1.15
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Class 10 Chapter 1 Example 1.16 to 1.20
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10th Maths Exercise 1.2 | 10th Maths Ex 1.2 | 10th Maths Chapter 1 Relations and Functions Exercise 1.2 | 10th Maths Chapter 1 Relations and Functions Exercise 1.1 | 10th Maths Chapter 1 Relations and Functions Exercise 1.3 | 10th Maths Chapter 1 Relations and Functions Exercise 1.4 | 10th Maths Chapter 1 Relations and Functions Exercise 1.5 | 10th Maths Chapter 1 Relations and Functions Exercise 1.6 | Class 10 Chapter 1 Relations and Functions Example 1.11 to 1.15 | Class 10 Chapter 1 Relations and Functions Example 1.6 to 1.10 | 10th Maths Example 1.6 | 10th Maths Example 1.7 | 10th Maths Example 1.8 | 10th Maths Example 1.9 | 10th Maths Example 1.10 | Class 10 Chapter 1 Relations and Functions Example 1.1 to 1.5 TN New Syllabus 10th Maths Chapter 1 Relations And Functions Example 1.1 1 Relations and Functions | 1.1 Introduction |1.2 Ordered Pair | 1.3 Cartesian Product | 1.4 Relations | 1.5 Functions | 1.6 Representation of Functions | 1.7 Types of functions | 1.8 Special cases of Functions | 1.9 Composition of Functions 1.10 Identifying the graphs of Linear, Quadratic, | Cubic and Reciprocal functions | TN (Samacheer) 10 Maths Relations and Functions New syllabus Ex 1.1 TN (Samacheer) 10 Maths New Syllabus Relations and Functions.
1. Using the functions f and g given below, find fog and gof Check
whether fog = gof.
(i) f(x) = x – 6, g(x) = x^2
Answer:
f(x) = x – 6, g(x) = x^2
fog = fog (x)
= f(g(x))
fog = f(x)^2
= x^2 – 6
gof = go f(x)
= g(x – 6)
= (x – 6)^2
= x^2 – 12x + 36
fog ≠ gof
(ii) f(x) = 2/x, g(x) = 2x^2 – 1
Answer:
f(x) – 2x; g(x) = 2x^2 – 1
fag = f[g (x)]
= f(2x^2 – 1)
= 2/2x^2−1
gof = g[f(x)]
= g (2x)
= 2 (2/x)^2 – 1
=2×4x^2−1
=8x^2−1
fog ≠ gof
(i) f(x) = x – 6, g(x) = x^2
Answer:
f(x) = x – 6, g(x) = x^2
fog = fog (x)
= f(g(x))
fog = f(x)^2
= x^2 – 6
gof = go f(x)
= g(x – 6)
= (x – 6)^2
= x^2 – 12x + 36
fog ≠ gof
(ii) f(x) = 2/x, g(x) = 2x^2 – 1
Answer:
f(x) – 2x; g(x) = 2x^2 – 1
fag = f[g (x)]
= f(2x^2 – 1)
= 2/2x^2−1
gof = g[f(x)]
= g (2x)
= 2 (2/x)^2 – 1
=2×4x^2−1
=8x^2−1
fog ≠ gof
(iii) f(x) = x+6/3, g(x) = 3–x
Answer:
f(x) = x+6/x, g(x) = 3 – x
fog = f[g(x)]
= f(3 – x)
(iv) f(x) = 3 + x, g(x) = x – 4
Answer:
f(x) = 3 + x ;g(x) = x – 4
fog = f[g(x)]
= f(x – 4)
= 3 + x – 4
= x – 1
gof = g[f(x)]
= g(3 + x)
= 3 + x – 4
= x – 1
fog = gof
Answer:
f(x) = x+6/x, g(x) = 3 – x
fog = f[g(x)]
= f(3 – x)
(iv) f(x) = 3 + x, g(x) = x – 4
Answer:
f(x) = 3 + x ;g(x) = x – 4
fog = f[g(x)]
= f(x – 4)
= 3 + x – 4
= x – 1
gof = g[f(x)]
= g(3 + x)
= 3 + x – 4
= x – 1
fog = gof
(v) f(x) = 4x^2 – 1,g(x) = 1 + x
Answer:
f(x) = 4x^2 – 1 ; g(x) = 1 + x
fog = f[g(x)]
= 4(1 + x)
= 4(1 + x)^2 – 1
= 4[1 + x^2 + 2x] – 1
= 4 + 4x^2 + 8x – 1
= 4x^2 + 8x + 3
gof = g [f(x)]
= g (4x^2 – 1)
= 1 + 4x^2 – 1
= 4x2
fog ≠ gof
Answer:
f(x) = 4x^2 – 1 ; g(x) = 1 + x
fog = f[g(x)]
= 4(1 + x)
= 4(1 + x)^2 – 1
= 4[1 + x^2 + 2x] – 1
= 4 + 4x^2 + 8x – 1
= 4x^2 + 8x + 3
gof = g [f(x)]
= g (4x^2 – 1)
= 1 + 4x^2 – 1
= 4x2
fog ≠ gof
2. Find the value of k, such that fog = gof
(i) f(x) = 3x + 2, g(x) = 6x – k
(ii) f(x) = 2x – k, g(x) = 4x + 5
Solution:
(i) f(x) = 3x + 2, g(x) = 6x – k
fog(x) = f(g(x)) = f(6x – k) = 3(6x – k) + 2
= 18x – 3k + 2 …………… (1)
gof(x) = g(f(x)) = g(3x + 2) = 6(3x + 2) – k
= 18x + 12 – k ……………. (2)
(1) = (2)
⇒ 18x – 3k + 2 = 18x + 12 – k
2k = -10
k = -5
(i) f(x) = 3x + 2, g(x) = 6x – k
(ii) f(x) = 2x – k, g(x) = 4x + 5
Solution:
(i) f(x) = 3x + 2, g(x) = 6x – k
fog(x) = f(g(x)) = f(6x – k) = 3(6x – k) + 2
= 18x – 3k + 2 …………… (1)
gof(x) = g(f(x)) = g(3x + 2) = 6(3x + 2) – k
= 18x + 12 – k ……………. (2)
(1) = (2)
⇒ 18x – 3k + 2 = 18x + 12 – k
2k = -10
k = -5
(ii) f(x) = 2x – k, g(x) = 4x + 5
fog(x) = f(g(x)) = f(4x + 5) = 2(4x + 5) – k
= 8x + 10 – k ……………… (1)
gof(x) = g(f(x)) = g(2x – k) = 4(2x – k) + 5
= 8x – 4k + 5 ……………. (2)
(1) = (2)
⇒ 8x + 10 – k = 8x – 4k + 5
3k = -5
k = −5/3
fog(x) = f(g(x)) = f(4x + 5) = 2(4x + 5) – k
= 8x + 10 – k ……………… (1)
gof(x) = g(f(x)) = g(2x – k) = 4(2x – k) + 5
= 8x – 4k + 5 ……………. (2)
(1) = (2)
⇒ 8x + 10 – k = 8x – 4k + 5
3k = -5
k = −5/3
3. If f(x) = 2x – 1, g(x) = x+1/2, show that f o g = g o f = x
Answer:
f(x) = 2x – 1 ; g(x) = x+1/2
fog = f[g(x)]
∴ fog = gof = x
Hence it is proved.
4. (i) If f (x) = x^2 – 1, g(x) = x – 2 find a, if gof(a) = 1.
(ii) Find k, if f(k) = 2k – 1 and fof (k) = 5.
Solution:
(i) f(x) = x^2 – 1, g(x) = x – 2
Given gof(a) = 1
gof(x) = g(f(x)
= g(x^2 – 1) = x^2 – 1 – 2
= x2 – 3
gof(a) ⇒ a^2 – 3 = 1 =+ a^2 = 4
a = ± 2
(ii) f(k) = 2k – 1
fo f(k) = 5
f(f(k)m = f(2k – 1) = 5
⇒ 2(2k – 1) – 1 = 5
4 k – 2 – 1 = 5 ⇒ 4k = 8
k = 2
5. Let A,B,C ⊂ N and a function f: A → B be defined by f(x) = 2x + 1
and g: B → C be defined by g(x) = x2 . Find the range of fog and gof.
Answer:
f(x) = 2x + 1 ; g(x) = x^2
fog = f[g(x)]
= f(x^2)
= 2x2 + 1
2x^2 + 1 ∈ N
g o f = g [f(x)]
= g (2x + 1)
g o f = (2x + 1)^2
(2x + 1)2 ∈ N
Range = {y/y = 2x^2 + 1, x ∈ N};
{y/y = (2x + 1)^2, x ∈ N)
6. If f(x) = x^2 – 1. Find (i)f(x) = x^2 – 1, (ii)fofof
Solution:
(i) f(x) = x^2 – 1
fof(x) = f(fx)) = f(x^2 – 1)
= (x^2 – 1 )^2 – 1;
= x^4 – 2x^2 + 1 – 1
= x4 – 2x^2
Answer:
f(x) = 2x – 1 ; g(x) = x+1/2
fog = f[g(x)]
∴ fog = gof = x
Hence it is proved.
(ii) Find k, if f(k) = 2k – 1 and fof (k) = 5.
Solution:
(i) f(x) = x^2 – 1, g(x) = x – 2
Given gof(a) = 1
gof(x) = g(f(x)
= g(x^2 – 1) = x^2 – 1 – 2
= x2 – 3
gof(a) ⇒ a^2 – 3 = 1 =+ a^2 = 4
a = ± 2
(ii) f(k) = 2k – 1
fo f(k) = 5
f(f(k)m = f(2k – 1) = 5
⇒ 2(2k – 1) – 1 = 5
4 k – 2 – 1 = 5 ⇒ 4k = 8
k = 2
Answer:
f(x) = 2x + 1 ; g(x) = x^2
fog = f[g(x)]
= f(x^2)
= 2x2 + 1
2x^2 + 1 ∈ N
g o f = g [f(x)]
= g (2x + 1)
g o f = (2x + 1)^2
(2x + 1)2 ∈ N
Range = {y/y = 2x^2 + 1, x ∈ N};
{y/y = (2x + 1)^2, x ∈ N)
Solution:
(i) f(x) = x^2 – 1
fof(x) = f(fx)) = f(x^2 – 1)
= (x^2 – 1 )^2 – 1;
= x^4 – 2x^2 + 1 – 1
= x4 – 2x^2
(ii) fofof = f o f(f(x))
= f o f (x^4 – 2x^2)
= f(f(x^4 – 2x^2))
= (x^4 – 2x^2)2 – 1
= x^8 – 4x^6 + 4x^4 – 1
7. If f : R → R and g : R → R are defined by f(x) = x^5 and g(x) =
x^4 then check if f, g are one – one and fog is one – one?
Answer:
f(x) = x^5 – It is one – one function
g(x) = x^4 – It is one – one function
fog = f[g(x)]
= f(x^4)
= (x^4)^5
fag = x20
It is also one-one function.
= f o f (x^4 – 2x^2)
= f(f(x^4 – 2x^2))
= (x^4 – 2x^2)2 – 1
= x^8 – 4x^6 + 4x^4 – 1
Answer:
f(x) = x^5 – It is one – one function
g(x) = x^4 – It is one – one function
fog = f[g(x)]
= f(x^4)
= (x^4)^5
fag = x20
It is also one-one function.
8. Consider the functions f(x), g(x), h(x) as given below. Show that
(fog)oh = fo(goh) in each case.
(i) f(x) = x – 1, g(x) = 3x + 1 and h(x) = x^2
(ii) f(x) = x^2, g(x) = 2x and h(x) = x + 4
(iii) f(x) = x – 4, g(x) = x^2 and h(x) = 3x – 5
Solution:
(i) f(x) = x – 1, g(x) = 3x + 1 and h(x) = x^2
f(x) = x – 1
g(x) = 3x + 1
f(x) = x^2
(fog)oh = fo(goh)
LHS = (fog)oh
fog = f(g(x)) = f(3x + 1) = 3x + 1 – 1 = 3x
(fog)oh = (fog)(h(x)) = (fog)(x^2 ) = 3^2 ……………. (1)
RHS = fo(goh)
goh = g(h(x)) = g(x^2) = 3x^2 + 1
fo(goh) = f(3x^2 + 1) = 3x^2 + 1 – 1= 3x^2 ………… (2)
LHS = RHS Hence it is verified.
(ii) f(x) = x^2, g(x) = 2x, h(x) = x + 4
(fog)oh = fo(goh)
LHS = (fog)oh
fog = f(g(x)) = f(2x) = (2x)^2 = 4x^2
(fog)oh = (fog) h(x) = (fog) (x + 4)
= 4(x + 4)^2 = 4(x^2 + 8x+16)
= 4x^2 + 32x + 64 ………….. (1)
RHS = fo(goh) goh = g(h(x)) = g(x + 4)
= 2(x + 4) = (2x + 8)
fo(goh) = f(goh) = f(2x + 8) = (2x + 8)^2
= 4x2 + 32x + 64 ……………… (2)
(1) = (2)
LHS = RHS
∴ (fog)oh = fo(goh) It is proved.
(i) f(x) = x – 1, g(x) = 3x + 1 and h(x) = x^2
(ii) f(x) = x^2, g(x) = 2x and h(x) = x + 4
(iii) f(x) = x – 4, g(x) = x^2 and h(x) = 3x – 5
Solution:
(i) f(x) = x – 1, g(x) = 3x + 1 and h(x) = x^2
f(x) = x – 1
g(x) = 3x + 1
f(x) = x^2
(fog)oh = fo(goh)
LHS = (fog)oh
fog = f(g(x)) = f(3x + 1) = 3x + 1 – 1 = 3x
(fog)oh = (fog)(h(x)) = (fog)(x^2 ) = 3^2 ……………. (1)
RHS = fo(goh)
goh = g(h(x)) = g(x^2) = 3x^2 + 1
fo(goh) = f(3x^2 + 1) = 3x^2 + 1 – 1= 3x^2 ………… (2)
LHS = RHS Hence it is verified.
(ii) f(x) = x^2, g(x) = 2x, h(x) = x + 4
(fog)oh = fo(goh)
LHS = (fog)oh
fog = f(g(x)) = f(2x) = (2x)^2 = 4x^2
(fog)oh = (fog) h(x) = (fog) (x + 4)
= 4(x + 4)^2 = 4(x^2 + 8x+16)
= 4x^2 + 32x + 64 ………….. (1)
RHS = fo(goh) goh = g(h(x)) = g(x + 4)
= 2(x + 4) = (2x + 8)
fo(goh) = f(goh) = f(2x + 8) = (2x + 8)^2
= 4x2 + 32x + 64 ……………… (2)
(1) = (2)
LHS = RHS
∴ (fog)oh = fo(goh) It is proved.
(iii) f(x) = x – 4, g(x) = x^2, h(x) = 3x – 5
(fog)oh = fo(goh)
LHS = (fog)oh
fog = f(g(x)) = f(x^2) = x^2 – 4
(fog)oh = (fog)(3x – 5) = (3x – 5)^2 – 4
= 9x^2 – 30x + 25 -4
= 9x^2 – 30x + 21 ………….. (1)
∴ RHS = fo(goh)
(goh) = g(h(x)) = g(3x – 5) = (3x – 5)^2
= 9x^2 – 30x + 25
fo(goh) = f(9x2 – 30 x + 25)
= 9x^2 – 30x + 25 – 4
= 9x^2 – 30x + 21 …………… (2)
(1) = (2)
LHS = RHS
∴ (fog)oh = fo(goh)
It is proved.
The linear equation is f(x) = ax + b
f(-1) = 3
a(-1) + b = 3
-a + b = 3 ….(1)
f(0) = -1
a(0) + b = -1
0 + b = -1
b = -1
Substitute the value of b = -1 in (1)
-a – 1 = 3
-a = 3 + 1
-a = 4
a = -4
∴ The linear equation is -4(x) -1 = -4x – 1 (or) – (4x + 1)
Given C(t) = 3t. To prove that the function is linear
C(at1) = 3a(t1)
C(bt2) = 3 b(t2)
C(at1 + bt2) = 3 [at1 + bt2] = 3at1 + 3bt2
= a(3t1) + b(3t2) = a[C(t1) + b(Ct2)]
∴ Superposition principle is satisfied.
Hence C(t) = 3t is linear function.
(fog)oh = fo(goh)
LHS = (fog)oh
fog = f(g(x)) = f(x^2) = x^2 – 4
(fog)oh = (fog)(3x – 5) = (3x – 5)^2 – 4
= 9x^2 – 30x + 25 -4
= 9x^2 – 30x + 21 ………….. (1)
∴ RHS = fo(goh)
(goh) = g(h(x)) = g(3x – 5) = (3x – 5)^2
= 9x^2 – 30x + 25
fo(goh) = f(9x2 – 30 x + 25)
= 9x^2 – 30x + 25 – 4
= 9x^2 – 30x + 21 …………… (2)
(1) = (2)
LHS = RHS
∴ (fog)oh = fo(goh)
It is proved.
9. Let f = {(-1, 3), (0, -1), (2, -9)} be a linear function from Z
into Z. Find f(x).
Answer:The linear equation is f(x) = ax + b
f(-1) = 3
a(-1) + b = 3
-a + b = 3 ….(1)
f(0) = -1
a(0) + b = -1
0 + b = -1
b = -1
Substitute the value of b = -1 in (1)
-a – 1 = 3
-a = 3 + 1
-a = 4
a = -4
∴ The linear equation is -4(x) -1 = -4x – 1 (or) – (4x + 1)
10. In electrical circuit theory, a circuit C(t) is called a
linear circuit if it satisfies the superposition principle given by
C(at1 + bt2) = aC(t1) + bC(t2), where a,b are constants. Show that the
circuit C(t) = 31 is linear.
Solution:Given C(t) = 3t. To prove that the function is linear
C(at1) = 3a(t1)
C(bt2) = 3 b(t2)
C(at1 + bt2) = 3 [at1 + bt2] = 3at1 + 3bt2
= a(3t1) + b(3t2) = a[C(t1) + b(Ct2)]
∴ Superposition principle is satisfied.
Hence C(t) = 3t is linear function.
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