Class 10 Maths (NCERT)
Chapter 8: Introduction to Trigonometry
Exercise 8.3 – Stepwise Solutions
Important Identities Used
- sin2θ + cos2θ = 1
- 1 + tan2θ = sec2θ
- 1 + cot2θ = cosec2θ
- tan θ = sin θ / cos θ, cot θ = cos θ / sin θ
- sec θ = 1/cos θ, cosec θ = 1/sin θ
1. Express sin A, sec A and tan A in terms of cot A.
Step 1: Use identity: 1 + cot2A = cosec2A
So, cosec A = √(1 + cot2A) (A is acute ⇒ positive root)
Step 2: sin A = 1 / cosec A
sin A = 1 / √(1 + cot2A)
Step 3: tan A = 1 / cot A
tan A = 1/cot A
Step 4: sec A = √(1 + tan2A)
sec A = √(1 + (1/cot A)2)
sec A = √((cot2A + 1)/cot2A)
sec A = √(1 + cot2A) / cot A
Final:
- sin A = 1 / √(1 + cot2A)
- tan A = 1 / cot A
- sec A = √(1 + cot2A) / cot A
2. Write all other trigonometric ratios of ∠A in terms of sec A.
Step 1: sec A = 1/cos A ⇒ cos A = 1/sec A
Step 2: sin2A = 1 − cos2A
sin2A = 1 − (1/sec A)2 = 1 − 1/sec2A
sin2A = (sec2A − 1)/sec2A
sin A = √(sec2A − 1) / sec A (acute angle)
Step 3: tan2A = sec2A − 1
tan A = √(sec2A − 1)
Step 4: cot A = 1/tan A
cot A = 1 / √(sec2A − 1)
Step 5: cosec A = 1/sin A
cosec A = sec A / √(sec2A − 1)
Final:
- cos A = 1/sec A
- sin A = √(sec2A − 1) / sec A
- tan A = √(sec2A − 1)
- cot A = 1 / √(sec2A − 1)
- cosec A = sec A / √(sec2A − 1)
3. Choose the correct option. Justify your choice.
(i) 9 sec2A − 9 tan2A = ?
Step 1: Factor 9
= 9(sec2A − tan2A)
Step 2: Use identity sec2A = 1 + tan2A
sec2A − tan2A = 1
So value = 9 × 1 = 9
Correct option: (B) 9
(ii) (1 + tan θ + sec θ)(1 + cot θ − cosec θ) = ?
Step 1: Rewrite each bracket using sin, cos.
1 + tan θ + sec θ = 1 + (sinθ/cosθ) + (1/cosθ)
= (cosθ + sinθ + 1)/cosθ
1 + cot θ − cosec θ = 1 + (cosθ/sinθ) − (1/sinθ)
= (sinθ + cosθ − 1)/sinθ
Step 2: Multiply:
= [(cosθ + sinθ + 1)(sinθ + cosθ − 1)] / (sinθ cosθ)
Step 3: Use (a+1)(a−1)=a2−1 with a = (sinθ + cosθ)
Numerator = (sinθ + cosθ)2 − 1
= (sin2θ + cos2θ + 2sinθcosθ) − 1
= (1 + 2sinθcosθ) − 1 = 2sinθcosθ
Step 4: So value = (2sinθcosθ)/(sinθcosθ) = 2
Correct option: (C) 2
(iii) (sec A + tan A)(1 − sin A) = ?
Step 1: Write in sin and cos
sec A + tan A = (1/cosA) + (sinA/cosA) = (1 + sinA)/cosA
Step 2: Multiply:
( (1 + sinA)/cosA ) (1 − sinA)
= (1 − sin2A)/cosA
= (cos2A)/cosA
= cos A
Correct option: (D) cos A
(iv) (1 + tan2A) / (1 + cot2A) = ?
Step 1: Use identities
1 + tan2A = sec2A
1 + cot2A = cosec2A
Step 2: Ratio
= sec2A / cosec2A
= (1/cos2A) / (1/sin2A)
= sin2A / cos2A
= tan2A
Correct option: (D) tan2A
4. Prove the following identities (acute angles).
(i) (cosec θ − cot θ)2 = (1 − cos θ)/(1 + cos θ)
Step 1: Start with LHS
(cosecθ − cotθ) = (1/sinθ) − (cosθ/sinθ) = (1 − cosθ)/sinθ
Step 2: Square
LHS = (1 − cosθ)2/sin2θ
Step 3: Use sin2θ = 1 − cos2θ = (1 − cosθ)(1 + cosθ)
LHS = (1 − cosθ)2 / [(1 − cosθ)(1 + cosθ)]
LHS = (1 − cosθ)/(1 + cosθ) = RHS
Hence proved.
(ii) cos A/(1 + sin A) + (1 + sin A)/cos A = 2 sec A
Step 1: Take LHS and make common denominator
LHS = [cos2A + (1 + sinA)2] / [cosA(1 + sinA)]
Step 2: Expand numerator
= [cos2A + (1 + 2sinA + sin2A)] / [cosA(1 + sinA)]
= [(sin2A + cos2A) + 1 + 2sinA] / [cosA(1 + sinA)]
= [1 + 1 + 2sinA] / [cosA(1 + sinA)]
= 2(1 + sinA)/[cosA(1 + sinA)]
= 2/cosA = 2 secA
Hence proved.
(iii) tan θ/(1 − cot θ) + cot θ/(1 − tan θ) = 1 + sec θ cosec θ
Step 1: Write tan and cot in sin, cos
tanθ/(1 − cotθ) = (sin/cos) / (1 − cos/sin)
= (sin/cos) / ((sin − cos)/sin)
= (sin/cos) × (sin/(sin − cos))
= sin2θ / [cosθ(sinθ − cosθ)]
cotθ/(1 − tanθ) = (cos/sin) / (1 − sin/cos)
= (cos/sin) / ((cos − sin)/cos)
= (cos/sin) × (cos/(cos − sin))
= cos2θ / [sinθ(cosθ − sinθ)]
= − cos2θ / [sinθ(sinθ − cosθ)]
Step 2: Add both terms
LHS = [ sin2θ/(cosθ(sinθ − cosθ)) ] − [ cos2θ/(sinθ(sinθ − cosθ)) ]
Step 3: Take common denominator sinθcosθ(sinθ − cosθ)
LHS = [ sin3θ − cos3θ ] / [ sinθcosθ(sinθ − cosθ) ]
Step 4: Use a3 − b3 = (a − b)(a2 + ab + b2)
Numerator = (sinθ − cosθ)(sin2θ + sinθcosθ + cos2θ)
= (sinθ − cosθ)(1 + sinθcosθ)
Step 5: Cancel (sinθ − cosθ) with (sinθ − cosθ) (note: (sinθ − cosθ)=−(cosθ−sinθ), cancellation valid)
LHS = (1 + sinθcosθ)/(sinθcosθ)
= 1/(sinθcosθ) + 1
= 1 + (1/sinθ)(1/cosθ)
= 1 + cosecθ · secθ = RHS
Hence proved.
(iv) (1 + sec A)/sec A = sin2A/(1 − cos A)
Step 1: Simplify LHS
(1 + secA)/secA = 1/secA + 1 = cosA + 1
Step 2: Simplify RHS
RHS = sin2A/(1 − cosA)
= (1 − cos2A)/(1 − cosA)
= (1 − cosA)(1 + cosA)/(1 − cosA)
= 1 + cosA
LHS = RHS. Hence proved.
(v) (cos A − sin A + 1)/(cos A + sin A − 1) = cosec A + cot A
Step 1: Start with LHS and multiply numerator & denominator by (cosA + sinA + 1)
LHS = (cosA − sinA + 1)(cosA + sinA + 1) / [(cosA + sinA − 1)(cosA + sinA + 1)]
Step 2: Denominator is (x−1)(x+1)=x2−1 with x=cosA+sinA
Den = (cosA + sinA)2 − 1
= (cos2A + sin2A + 2sinAcosA) − 1
= (1 + 2sinAcosA) − 1 = 2sinAcosA
Step 3: Numerator is ( (cosA+1) − sinA )((cosA+1) + sinA )
= (cosA + 1)2 − sin2A
= (cos2A + 2cosA + 1) − sin2A
= (cos2A − sin2A) + 2cosA + 1
= (cos2A) + 2cosA + 1
Better simplify using sin2+cos2=1:
(cosA + 1)2 − sin2A = cos2A + 2cosA + 1 − sin2A
= (cos2A − sin2A) + 2cosA + 1
= (cos2A − (1 − cos2A)) + 2cosA + 1
= (2cos2A − 1) + 2cosA + 1
= 2cosA(cosA + 1)
Step 4: So
LHS = [2cosA(cosA + 1)] / [2sinAcosA] = (cosA + 1)/sinA
= 1/sinA + cosA/sinA
= cosecA + cotA
Hence proved.
(vi) √((1 + sin A)/(1 − sin A)) = sec A + tan A
Step 1: Start with LHS
√((1 + sinA)/(1 − sinA))
Step 2: Multiply inside by (1 + sinA)/(1 + sinA)
= √( (1 + sinA)2 / (1 − sin2A) )
Step 3: 1 − sin2A = cos2A
= √( (1 + sinA)2 / cos2A )
Step 4: Take square root (acute ⇒ cosA>0)
= (1 + sinA)/cosA
= 1/cosA + sinA/cosA
= secA + tanA
Hence proved.
(vii) (sin θ − 2 sin3θ) / (2 cos3θ − cos θ) = tan θ
Step 1: Factor numerator and denominator
Numerator = sinθ(1 − 2sin2θ)
Denominator = cosθ(2cos2θ − 1)
Step 2: Use sin2θ = 1 − cos2θ
1 − 2sin2θ = 1 − 2(1 − cos2θ) = 1 − 2 + 2cos2θ = 2cos2θ − 1
Step 3: Substitute
LHS = sinθ(2cos2θ − 1) / [cosθ(2cos2θ − 1)]
= sinθ/cosθ = tanθ
Hence proved.
(viii) (sinA + cosecA)2 + (cosA + secA)2 = 7 + tan2A + cot2A
Step 1: Expand both squares
(sinA + cosecA)2 = sin2A + cosec2A + 2(sinA·cosecA)
= sin2A + cosec2A + 2
(cosA + secA)2 = cos2A + sec2A + 2(cosA·secA)
= cos2A + sec2A + 2
Step 2: Add
LHS = (sin2A + cos2A) + (cosec2A + sec2A) + (2 + 2)
= 1 + (cosec2A + sec2A) + 4
= 5 + cosec2A + sec2A
Step 3: Use identities
cosec2A = 1 + cot2A
sec2A = 1 + tan2A
LHS = 5 + (1 + cot2A) + (1 + tan2A)
= 7 + tan2A + cot2A = RHS
Hence proved.
(ix) (cosecA − sinA)(secA − cosA) = 1/(tanA + cotA)
Step 1: Simplify each bracket
cosecA − sinA = (1/sinA) − sinA = (1 − sin2A)/sinA = cos2A/sinA
secA − cosA = (1/cosA) − cosA = (1 − cos2A)/cosA = sin2A/cosA
Step 2: Multiply
LHS = (cos2A/sinA) (sin2A/cosA)
= (sinA cosA)
Step 3: Simplify RHS
tanA + cotA = (sinA/cosA) + (cosA/sinA)
= (sin2A + cos2A)/(sinA cosA)
= 1/(sinA cosA)
So, 1/(tanA + cotA) = sinA cosA
LHS = RHS. Hence proved.
(x) (1 + tan2A)/(1 + cot2A) = ((1 − tanA)/(1 − cotA))2 = tan2A
Part 1: (1 + tan2A)/(1 + cot2A)
= sec2A / cosec2A
= (1/cos2A)/(1/sin2A)
= sin2A/cos2A
= tan2A
Part 2: ((1 − tanA)/(1 − cotA))2
Step 1: Write cotA = 1/tanA
1 − cotA = 1 − 1/tanA = (tanA − 1)/tanA
Step 2: Form the fraction
(1 − tanA)/(1 − cotA) = (1 − tanA) / ((tanA − 1)/tanA)
= (1 − tanA) × (tanA/(tanA − 1))
= (-(tanA − 1)) × (tanA/(tanA − 1))
= -tanA
Step 3: Square
((1 − tanA)/(1 − cotA))2 = (-tanA)2 = tan2A
Hence proved.
Final Answers (Quick)
1) sinA = 1/√(1+cot²A), secA = √(1+cot²A)/cotA, tanA = 1/cotA
2) cosA = 1/secA, sinA = √(sec²A−1)/secA, tanA = √(sec²A−1), cotA = 1/√(sec²A−1), cosecA = secA/√(sec²A−1)
3) (i) 9 (B), (ii) 2 (C), (iii) cosA (D), (iv) tan²A (D)
4) All identities (i) to (x) proved above.