Class 11 RD Sharma Solutions – Chapter 5 Trigonometric Functions – Exercise 5.1 | Set 2

Last Updated : 21 Feb, 2021

Question 14. Prove that $\frac{(1+cotθ+tanθ)(sinθ-cosθ)}{sec^3θ-cosec^3θ}=sin^2θcos^2θ$

Solution:

We have

$\frac{(1+cotθ+tanθ)(sinθ-cosθ)}{sec^3θ-cosec^3θ}=sin^2θcos^2θ$

Taking LHS

= $\frac{(1+cotθ+tanθ)(sinθ-cosθ)}{sec^3θ-cosec^3θ}$

= $\frac{(1+\frac{cosθ}{sinθ}+\frac{sinθ}{cosθ})(sinθ-cosθ)}{\frac{1}{cos^3θ}-\frac{1}{sin^3θ}}$

= $\frac{(\frac{cosθsinθ+cos^2θ+sin^2θ}{sinθcosθ})(sinθ-cosθ)}{\frac{sin^3θ-cos^3θ}{sin^3θcos^3θ}}$

= $\frac{(1+cosθsinθ)(sinθ-cosθ)(sin^2θcos^2θ)}{sin^3θ-cos^3θ}$

= $\frac{(1+cosθsinθ)(sinθ-cosθ)(sin^2θcos^2θ)}{(sinθ-cosθ)(sin^2θ+cos^2θ+cosθsinθ)}$

= $\frac{(1+cosθsinθ)(sin^2θcos^2θ)}{(1+cosθsinθ)}$

= sin²θcos²θ

Hence, LHS = RHS (Proved)

Question 15. Prove that $\frac{2sinθcosθ-cosθ}{1-sinθ+sin^2θ-cos^2θ}=cotθ$

Solution:

We Have

$\frac{2sinθcosθ-cosθ}{1-sinθ+sin^2θ-cos^2θ}=cotθ$

Taking LHS

= $\frac{2sinθcosθ-cosθ}{1-sinθ+sin^2θ-cos^2θ}$

= $\frac{cosθ(2sinθ-1)}{1-cos^2θ-sinθ+sin^2θ}$

= $\frac{cosθ(2sinθ-1)}{sin^2θ-sinθ+sin^2θ}$

= $\frac{cosθ(2sinθ-1)}{2sin^2θ-sinθ}$

= $\frac{cosθ(2sinθ-1)}{sinθ(2sinθ-1)}$

= cosθ/sinθ

= cotθ

Hence, LHS = RHS(Proved)

Question 16. Prove that cosθ(tanθ + 2)(2tanθ + 1) = 2secθ + 5sinθ

Solution:

We have

cosθ(tanθ + 2)(2tanθ + 1) = 2secθ + 5sinθ

Taking LHS

= cosθ(tanθ + 2)(2tanθ + 1)

= $cosθ(\frac{sinθ}{cosθ}+2)(\frac{2sinθ}{cosθ}+1)$

= $cosθ\frac{(sinθ+2cosθ)(2sinθ+cosθ)}{cos^2θ}$

= $\frac{(2sin^2θ+sinθcosθ+4sinθcosθ+2cos^2θ)}{cosθ}$

= $\frac{2(sin^2θ+cos^2θ)+5sinθcosθ}{cosθ}$

= $\frac{2+5sinθcosθ}{cosθ}$

= $\frac{2}{cosθ}+\frac{5sinθcosθ}{cosθ}$

= 2secθ + 5sinθ

Hence, LHS = RHS(Proved)

Question 17. If x = $\frac{2sinθ}{1+cosθ+sinθ}$ , prove that $\frac{1-cosθ+sinθ}{1+sinθ}$ is also equal to x.

Solution:

We have

x = $\frac{2sinθ}{1+cosθ+sinθ}$

Taking LHS

= $\frac{2sinθ(1-cosθ+sinθ)}{(1+cosθ+sinθ)(1-cosθ+sinθ)}$

= $\frac{2sinθ(1-cosθ+sinθ)}{(1+sinθ)^2-cos^2θ}$

= $\frac{2sinθ-2sinθcosθ+2sin^2θ}{1+sin^2θ +2sinθ-cos^2θ}$

= $\frac{2sinθ(1+cosθ-sinθ)}{2sin^2θ+2sinθ}$

= $\frac{1+cosθ-sinθ}{1+sinθ}$

Question 18. If $sin θ=\frac{a^2+b^2}{a^2−b^2}$ , then find the values of tanθ, secθ, and cosecθ

Solution:

We have

$sin θ=\frac{Perpendicular}{Hypotenuse}=\frac{a^2+b^2}{a^2−b^2}$

As we know that

cosθ = √1 – sin²θ -(1)

Now put the value of sinθ in eq(1)

cosθ = $\sqrt{1-\frac{(a^2-b^2)^2}{(a^2+b^2)^2}}$

= $\sqrt{\frac{(a^2+b^2)^2-(a^2-b^2)^2}{(a^2+b^2)^2}}$

= $\sqrt{\frac{(a^4+b^4+2a^2b^2)-(a^4+b^4-2a^2b^2)}{(a^2+b^2)^2}}$

= $\sqrt{\frac{4a^2b^2}{(a^2+b^2)^2}}$

= $\frac{2ab}{(a^2+b^2)}$

So the value of cosθ = $\frac{2ab}{(a^2+b^2)}$

Now,

tanθ = $\frac{Perpendicular}{Base}=\frac{a^2−b^2}{2ab}$

secθ = $\frac{Hypotenuse}{Base}=\frac{a^2+b^2}{2ab}$

cosecθ = $\frac{Hypotenuse}{Perpendicular}=\frac{a^2+b^2}{a^2-b^2}$

Alternative Method:

We have

$sin θ=\frac{Perpendicular}{Hypotenuse}=\frac{a^2+b^2}{a^2−b^2}$

We draw a △PQR right-angled at Q PR = a²+ b²andPQ = a²– b²

By Pythagoras theorem, we have

PR²= PQ²+ QR²

QR²= (a²+ b²)²– (a²– b²)²

QR²= (a⁴+ b⁴+ 2a²b²) − (a⁴+ b⁴− 2a²b²)

QR²= 4a²b²

QR = 2ab

cosθ = $\frac{2ab}{a^2 +b^2}$

Now,

tanθ = $\frac{Perpendicular}{Base}=\frac{a^2−b^2}{2ab}$

secθ = $\frac{Hypotenuse}{Base}=\frac{a^2+b^2}{2ab}$

cosecθ = $\frac{Hypotenuse}{Perpendicular}=\frac{a^2+b^2}{a^2-b^2}$

Question 19. If tanθ = a/b, then find the value of $\sqrt{\frac{a+b}{a-b}}+ \sqrt{\frac{a-b}{a+b}}$

Solution:

We have

= $\sqrt{\frac{a+b}{a-b}}+ \sqrt{\frac{a-b}{a+b}}$

= $\sqrt{\frac{\frac{a}{b}+1}{\frac{a}{b}-1}}+ \sqrt{\frac{\frac{a}{b}-1}{\frac{a}{b}+1}}$

Now put tanθ = a/b

= $\sqrt{\frac{tanθ +1}{tanθ-1}}+\sqrt{\frac{tanθ -1}{tanθ+1}}$

= $\sqrt{\frac{\frac{sinθ}{cosθ}+1}{\frac{sinθ}{cosθ}-1}}+\sqrt{\frac{\frac{sinθ}{cosθ}-1}{\frac{sinθ}{cosθ}+1}}$

= $\sqrt{\frac{sinθ +cosθ}{sinθ-cosθ}}+\sqrt{\frac{sinθ -cosθ}{sinθ+cosθ}}$

= $\frac{sinθ+cosθ+sinθ-cosθ}{\sqrt{sin^2θ-cos^2θ}}$

= $\frac{2sinθ}{\sqrt{sin^2θ-cos^2θ}}$

Question 20. If tanθ = a/b, show that $\frac{asinθ-bcosθ}{asinθ+bcosθ}=\frac{a^2-b^2}{a^2+b^2}$ .

Solution:

We have

$\frac{asinθ-bcosθ}{asinθ+bcosθ}=\frac{a^2-b^2}{a^2+b^2}$

Taking LHS

= $\frac{asinθ-bcosθ}{asinθ+bcosθ}$

Dividing denominator and Numerator by cosθ

= $\frac{\frac{asinθ-bcosθ}{cosθ}}{\frac{asinθ+bcosθ}{cosθ}}$

= $\frac{\frac{asinθ}{cosθ}-\frac{bcosθ}{cosθ}}{\frac{asinθ}{cosθ}+\frac{bcosθ}{cosθ}}$

= $\frac{atanθ-b}{atanθ+b}$

= $\frac{a(\frac{a}{b})-b}{a(\frac{a}{b})+b}$

= $\frac{\frac{a^2-b^2}{b}}{\frac{a^2+b^2}{b}}$

= $\frac{a^2-b^2}{a^2+b^2}$

Hence, LHS = RHS(Proved)

Question 21. If cosecθ – sinθ = a³, secθ – cosθ = b³, then prove that a²b²(a²+ b²) = 1.

Solution:

Given: cosecθ – sinθ = a³

1/sinθ − sinθ = a³

$\frac{1-sin^2θ}{sinθ}$ = a³

cos²θ/sinθ = a³

a = (cos²θ/sinθ)^1/3

Similarly, b = (sin²θ/cosθ)^1/3

Now putting the values of a and b in the following equation

Taking LHS

= a²b²(a²+ b²)

= a⁴b²+ a²b⁴

= $(\frac{cos^2θ}{sinθ})^\frac{4}{3}(\frac{sin^2θ}{cosθ})^\frac{2}{3}+ (\frac{cos^2θ}{sinθ})^\frac{2}{3}(\frac{sin^2θ}{cosθ})^\frac{4}{3}$

= cos^6/3θ + sin^6/3θ

= cos²θ + sin²θ

= 1

Hence, LHS = RHS (Proved)

Question 22. If cotθ(1 + sinθ) = 4m and cotθ(1 − sinθ) = 4n, prove that (m²– n²)² = mn.

Solution:

Given: cotθ(1 + sinθ) = 4m and cotθ(1 − sinθ) = 4n

Multiplying both the equations

16mn = cot²θ(1 – sin²θ)

16mn = $\frac{cos^2θ}{sin^2θ}(cos^2θ)$

16mn = cos⁴θ/sin²θ

mn = cos⁴θ/16sin²θ -(1)

Now squaring the given equations

16m²= cot²θ(1 + sinθ)²and 16n²= cot²θ(1 – sinθ)²

On subtracting both the equation, we get

16m²– 16n²= cot²θ(1 + sinθ)²– cot²θ(1 – sinθ)²

16(m²– n²) = cot²θ((1 + sinθ)²– (1 – sinθ)²)

16(m²– n²) = $\frac{cos^2θ}{sin^2θ}(4sinθ)$

(m²– n²) = cos²θ/4sinθ

On squaring both side, we get

(m² – n²)²= cos⁴θ/16sinθ -(2)

From equation(1) and (2)

(m² – n²)²= mn

Hence proved

Question 23. If sinθ + cosθ = m then prove that sin⁶θ + cos⁶θ = $\frac{4−3(m^2−1)^2}{4}$ , where m²≤ 2.

Solution:

Given: sinθ + cosθ = m

On squaring both side, we get

(sinθ + cosθ)²= m²

= sin²θ + cos²θ + 2sinθcosθ = m²

= 2sinθcosθ = m²− 1

Now,

Taking LHS

= sin⁶θ + cos⁶θ

Using a³+ b³= (a + b)(a²+ b²− ab)

= (sin²θ)³+ (cos²θ)³

= (sin²θ + cos²θ)(sin⁴θ + cos⁴θ − sin²θcos²θ)

= (1)((sin²θ)²+ (cos²θ)²− sin²θcos²θ)

= (sin²θ + cos²θ)²− 2sin²θcos²θ − sin²θcos²θ

= (1 − 3sin²θcos²θ)

= $1−3(\frac{m^2-1}{2})^2$

= $1−3\frac{(m^2-1)^2}{4}$

= $\frac{4-3(m^2-1)^2}{4}$

Hence, Proved.

Question 24. If a = secθ – tanθ and b = cosecθ + cotθ, then show that ab + a – b + 1 = 0.

Solution:

We have

a = secθ – tanθ and b = cosecθ + cotθ

and we have to proof that

ab + a – b + 1 = 0

So, taking LHS

ab + a – b + 1

Now put the values of a and b, we get

= (secθ – tanθ)(cosecθ + cotθ) – (secθ – tanθ) + (cosecθ + cotθ) + 1

= (1/cosθ – sinθ/cosθ)(1/sinθ + cosθ/sinθ) – (1/cosθ – sinθ/cosθ) + (1/sinθ + cosθ/sinθ) + 1

= 1/cosθsinθ + 1/cosθ x cosθ/sinθ – sinθ/cosθ x 1/sinθ – (sinθ/cosθ) x (cosθ/sinθ) + 1/cosθ – sinθ/cosθ – 1/sinθ – cosθ/sinθ + 1

= 1/cosθsinθ + 1/sinθ – 1/cosθ – 1 + 1/cosθ – sinθ/cosθ – 1/sinθ – cosθ/sinθ + 1

= 1/cosθsinθ – sinθ/cosθ – cosθ/sinθ

= 1 – sin²θ – cos²θ/sinθcosθ

= 1 – (sin²θ + cos²θ)/sinθcosθ

= 1 – 1/sinθcosθ

= 0

Hence, LHS = RHS (Proved)

Question 25. $|\sqrt\frac{1-sinθ}{1+sinθ}+\sqrt\frac{1+sinθ}{1-sinθ}|=\frac{-2}{cosθ}$ , where π/2 < θ < π.

Solution:

We have

$|\sqrt\frac{1-sinθ}{1+sinθ}+\sqrt\frac{1+sinθ}{1-sinθ}|=\frac{-2}{cosθ}$

Taking LHS

= $|\sqrt\frac{1-sinθ}{1+sinθ}+\sqrt\frac{1+sinθ}{1-sinθ}|$

= $\sqrt(\frac{1-sinθ}{1+sinθ})(\frac{1-sinθ}{1-sinθ})+\sqrt(\frac{1+sinθ}{1-sinθ})(\frac{1+sinθ}{1+sinθ})$

= $\sqrt\frac{(1-sinθ)^2}{(1)^2-(sinθ)^2}+\sqrt\frac{(1+sinθ)^2}{(1)^2-(sinθ)^2}$

= $\sqrt\frac{(1-sinθ)^2}{1-sin^2θ}+\sqrt\frac{(1+sinθ)^2}{1-sin^2θ}$

= $\sqrt\frac{(1-sinθ)^2}{cos^2θ}+\sqrt\frac{(1+sinθ)^2}{cos^2θ}$

= $\frac{(1-sinθ)}{cosθ}+\frac{(1+sinθ)}{cosθ}$

= $\frac{(1-sinθ+1+sinθ)}{cosθ}$

= 2/cosθ

Since π/2 < θ < π ,where cosθ is negative

So, -2/cosθ

Hence, LHS = RHS (Proved)

Question 26 (i). If T_n = sinⁿθ + cosⁿθ, prove that

\frac{T_3-T_5}{T_1}=\frac{T_5-T_7}{T_5}

Solution:

LHS = $\frac{T_3-T_5}{T_1}=\frac{(sin^3θ+cos^3θ)-(sin^5θ+cos^5θ)}{sinθ+cosθ}$

$=\frac{sin^3θ-sin^5θ+cos^3θ-cos^5θ}{sinθ+cosθ}$

$=\frac{sin^3θ(1-sin^2θ)+cos^3θ(1-cos^2θ)}{sinθ+cosθ}$

$=\frac{sin^3θcos^2θ+cos^3θsin^2θ}{sinθ+cosθ}$

$=\frac{sin^2θcos^2θ(sinθ+cosθ)}{sinθ+cosθ}$

= sin²θcos²θ

RHS = $\frac{T_5-T_7}{T_5}$

= $\frac{(sin^5θ+cos^5θ)-(sin^7θ+cos^7θ)}{sin^3θ+cos^3θ}$

$=\frac{sin^5θ-sin^7θ+cos^5θ-cos^7θ}{sin^3θ+cos^3θ}$

$=\frac{sin^5θ(1-sin^2θ)+cos^5θ(1-cos^2θ)}{sin^3θ+cos^3θ}$

$=\frac{sin^5θcos^2θ+cos^5θsin^2θ}{sin^3θ+cos^3θ}$

$=\frac{sin^2θcos^2θ(sin^3θ+cos^3θ)}{sin^3θ+cos^3θ}$

= sin2θcos²θ

Question 26 (ii). If T_n = sinⁿθ + cosⁿθ, prove that

2T₆– 3T₄+ 1 = 0

Solution:

LHS = 2(sin⁶θ + cos⁶θ) – 3(sin⁴θ + cos⁴θ) + 1

Using (a³+ b³) = (a + b)(a²+ b²– ab)

= 2(sin²θ + cos²θ)(sin⁴θ + cos⁴θ – sin²θcos²θ) – 3(sin⁴θ + cos⁴θ) + 1

= 2(1)(sin⁴θ + cos⁴θ – sin²θcos²θ) – 3(sin⁴θ + cos⁴θ) + 1

= 2sin⁴θ + 2cos⁴θ – 2sin²θcos²θ – 3sin⁴θ – 3cos⁴θ + 1

= -sin⁴θ – cos⁴θ – 2sin²θcos²θ + 1

= -(sin²θ + cos²θ)²+ 1

= -1 + 1 = 0 = RHS (Hence Proved)

Question 26 (iii). If T_n = sinⁿθ + cosⁿθ, prove that

6T₁₀– 15T₈+ 10T₆– 1 = 0

Solution:

T₆= sin⁶θ + cos⁶θ

Using a³+ b³= (a + b)(a²+ b²− ab)

= (sin²x)³+ (cos²x)³

= (sin²x + cos²x)(sin⁴x + cos⁴x − sin²xcos²x)

Using a² + b² = (a + b)²− 2ab

= (1)(sin⁴x + cos⁴x − sin²xcos²x)

= (sin²x)²+ (cos²x)²− sin²xcos²x

= (sin²x + cos²x)²− 3sin²xcos²

= 1 − 3sin²xcos²x

Similarly, we get the values of T₈ & T₁₀

T₈= (sin⁶x + cos⁶x)(sin²x + cos²x) − sin²xcos²x(sin⁴x + cos⁴x)

= 1 − 3sin²xcos²x − sin²xcos²x(1 − 2sin²xcos²x)

= 1 − 4sin²xcos²x + 2sin⁴xcos⁴x

T₁₀= sin¹⁰θ + cos¹⁰θ

= (sin⁶θ + cos6θ)(sin⁴θ + cos⁴θ) − sin4θcos⁴θ(sin²θ + cos²θ)

= (1 − 3sin²xcos²x)(1 − 2sin²xcos²x) − sin⁴xcos⁴x

= 1 − 5sin²xcos²x + 5sin⁴xcos⁴x

On putting the values of T6, T8 and T10 in the following equation

6T₁₀– 15T₈+ 10T₆– 1

We get the value 0.

Hence Proved

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Class 11 RD Sharma Solutions - Chapter 5 Trigonometric Functions - Exercise 5.1 | Set 1

Class 11 RD Sharma Solutions - Chapter 5 Trigonometric Functions - Exercise 5.2

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Chapter 1: Sets

Chapter 2: Relations

Chapter 3: Functions

Chapter 4: Measurement of Angles

Chapter 5: Trigonometric Functions

Chapter 6: Graphs of Trigonometric Functions

Chapter 7: Trigonometric Ratios of Compound Angles

Chapter 8: Transformation Formulae

Chapter 9: Trigonometric Ratios of Multiple and Sub Multiple Angles

Chapter 10: Sine and Cosine Formulae and their Applications

Chapter 11: Trigonometric Equations

Chapter 12: Mathematical Induction

Chapter 13: Complex Numbers

Chapter 15: Linear Inequations

Chapter 16: Permutations

Chapter 17: Combinations

Chapter 18: Binomial Theorem

Chapter 19: Arithmetic Progressions

Chapter 20: Geometric Progressions

Chapter 21: Some Special Series

Chapter 22: Brief Review of Cartesian System of Rectangular Coordinates

Chapter 23: The Straight Lines

Chapter 24: The Circle

Chapter 25: Parabola

Chapter 26: Ellipse

Chapter 27: Hyperbola

Chapter 28: Introduction to 3D Coordinate Geometry

Chapter 29: Limits

Chapter 30: Derivatives

Chapter 31: Mathematical Reasoning

Chapter 32: Statistics

Chapter 33: Probability

Class 11 RD Sharma Solutions – Chapter 5 Trigonometric Functions – Exercise 5.1 | Set 2

Question 14. Prove that

Question 15. Prove that

Question 16. Prove that cosθ(tanθ + 2)(2tanθ + 1) = 2secθ + 5sinθ

Question 17. If x = , prove that is also equal to x.

Question 18. If , then find the values of tanθ, secθ, and cosecθ

Question 19. If tanθ = a/b, then find the value of

Question 20. If tanθ = a/b, show that .

Question 21. If cosecθ – sinθ = a3, secθ – cosθ = b3, then prove that a2b2(a2 + b2) = 1.

Question 22. If cotθ(1 + sinθ) = 4m and cotθ(1 − sinθ) = 4n, prove that (m2 – n2)2 = mn.

Question 23. If sinθ + cosθ = m then prove that sin6θ + cos6θ = , where m2 ≤ 2.

Question 24. If a = secθ – tanθ and b = cosecθ + cotθ, then show that ab + a – b + 1 = 0.

Question 25. , where π/2 < θ < π.

Question 26 (i). If Tn = sinnθ + cosnθ, prove that

\frac{T_3-T_5}{T_1}=\frac{T_5-T_7}{T_5}

Question 26 (ii). If Tn = sinnθ + cosnθ, prove that

2T6 – 3T4 + 1 = 0

Question 26 (iii). If Tn = sinnθ + cosnθ, prove that

6T10 – 15T8 + 10T6 – 1 = 0

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Question 14. Prove that $\frac{(1+cotθ+tanθ)(sinθ-cosθ)}{sec^3θ-cosec^3θ}=sin^2θcos^2θ$

Question 15. Prove that $\frac{2sinθcosθ-cosθ}{1-sinθ+sin^2θ-cos^2θ}=cotθ$

Question 17. If x = $\frac{2sinθ}{1+cosθ+sinθ}$ , prove that $\frac{1-cosθ+sinθ}{1+sinθ}$ is also equal to x.

Question 18. If $sin θ=\frac{a^2+b^2}{a^2−b^2}$ , then find the values of tanθ, secθ, and cosecθ

Question 19. If tanθ = a/b, then find the value of $\sqrt{\frac{a+b}{a-b}}+ \sqrt{\frac{a-b}{a+b}}$

Question 20. If tanθ = a/b, show that $\frac{asinθ-bcosθ}{asinθ+bcosθ}=\frac{a^2-b^2}{a^2+b^2}$ .

Question 21. If cosecθ – sinθ = a³, secθ – cosθ = b³, then prove that a²b²(a²+ b²) = 1.

Question 22. If cotθ(1 + sinθ) = 4m and cotθ(1 − sinθ) = 4n, prove that (m²– n²)² = mn.

Question 23. If sinθ + cosθ = m then prove that sin⁶θ + cos⁶θ = $\frac{4−3(m^2−1)^2}{4}$ , where m²≤ 2.

Question 25. $|\sqrt\frac{1-sinθ}{1+sinθ}+\sqrt\frac{1+sinθ}{1-sinθ}|=\frac{-2}{cosθ}$ , where π/2 < θ < π.

Question 26 (i). If T_n = sinⁿθ + cosⁿθ, prove that

Question 26 (ii). If T_n = sinⁿθ + cosⁿθ, prove that

2T₆– 3T₄+ 1 = 0

Question 26 (iii). If T_n = sinⁿθ + cosⁿθ, prove that

6T₁₀– 15T₈+ 10T₆– 1 = 0