Class 12 RD Sharma Solutions - Chapter 19 Indefinite Integrals - Exercise 19.25

Evaluate the following integrals:

Question 41. ∫cos^-1⁡((1 - x²)/(1 + x²))dx

Solution:

Given that, I = ∫cos^-1⁡((1 - x²)/(1 + x²))dx)
Let us considered x = tan⁡t
dx = sec²tdt
I = ∫cos^-1⁡((1 - tan²t)/(1 + tan²⁡t)) sec²tdt
= ∫cos^-1(cos⁡2t)sec²tdt
= ∫2tsec²⁡tdt
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = 2[t∫sce²tdt - ∫(1∫sec²⁡tdt)dt]
= 2[t × tan²t - ∫tan⁡tdt]
= 2[t × tan²t - log⁡sec⁡t] + c
= 2[xtan^-1x - log⁡√(1 + x²)] + c
Hence, I = 2xtan^-1x - log⁡|1 + x²| + c

Question 42. ∫tan^-1⁡(2x/(1 - x²))dx

Solution:

Given that, I = ∫tan^-1⁡(2x/(1 - x²))dx
Let us considered x = tan⁡θ
dx = sec²θdθ
I = ∫tan^-1⁡((2tan⁡θ)/(1 - tan²θ)) sec²θdθ
= ∫tan^-1⁡(tan⁡2θ)sec²θdθ
= ∫2θsec²θdθ
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = 2[θ∫sec²θdθ - ∫(1∫ sec²⁡θdθ)dθ]
= 2[θtan⁡θ - ∫tan⁡θdθ]
= 2[θtan⁡θ - log⁡sec⁡θ] + c
= 2[xtan^-1⁡x - log⁡√(1 + x²)] + c
Hence, I = 2xtan^-1⁡x - log⁡|1 + x²| + c

Question 43. ∫(x + 1)log⁡xdx

Solution:

Given that, I = ∫(x + 1)log⁡xdx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = log⁡x∫ (x + 1)dx - ∫(1/x ∫(x + 1)dx)dx
= (x²/2 + x)log⁡x - ∫1/x (x²/2 + x)dx
= (x²/2 + x)log⁡x - 1/2 ∫xdx - ∫dx
= (x + x²/2)log⁡x - 1/2 × x²/2 - x + c
Hence, I = (x + x²/2)log⁡x - 1/2 × x²/2 - x + c

Question 44. ∫ x² tan^-1xdx

Solution:

Given that, I = ∫ x² tan^-1⁡xdx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = tan^-1⁡x∫x² dx - ∫(1/(1 + x²) ∫x² dx) dx
= tan^-1⁡x(x³/3) - 1/3∫x³/(1 + x²) dx
= 1/3 x³ tan^-1⁡x - 1/3 ∫(x - x/(1 + x²))dx
= 1/3 x³ tan^-1⁡x - 1/3 × x²/2 + 1/3 ∫x/(1 + x²) dx
Hence, I = 1/3 x³tan^-1x - 1/6 x²+ 1/6 log⁡|1 + x²| + c

Question 45. ∫(e^logx+ sin⁡x) cos⁡xdx

Solution:

Given that, I = ∫(e^logx+ sin⁡x)cos⁡xdx
= ∫(x + sin⁡x)cos⁡xdx
= ∫xcos⁡xdx + ∫sin⁡xcos⁡xdx
= [x∫cos⁡xdx - ∫(1]cos⁡xdx)dx] + 1/2 ∫sin⁡2xdx
= [xsin⁡x - ∫ sin⁡xdx] + 1/2 (-(cos⁡2x)/2) + c
I = xsin⁡x+cos⁡x - 1/4 cos⁡2x + c
= xsin⁡x + cos⁡x - 1/4 [1 - 2sin²⁡x] + c
= xsin⁡x + cos⁡x - 1/4 + 1/2 sin²x + c
= xsin⁡x + cos⁡x - 1/4 + 1/2 sin²x + c
Hence, I = xsin⁡x + cos⁡x + 1/2 sin²⁡x + d [d = c-/4]

Question 46. ∫((xtan^-1⁡x))/(1 + x²)^3/2 dx

Solution:

Given that, I = ∫((xtan^-1⁡x))/(1 + x²)^3/2dx
Let us considered tan^-1⁡x = t
1/(1 + x²) dx = dt
I = ∫(t tan⁡t)/√(1 + tan²⁡t) dt
= ∫(t × tan⁡t)/(sec⁡t) dt
= ∫t (sin⁡t)/(cos⁡t) cos⁡tdt
= ∫tsin⁡tdt
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = [t]sin⁡tdt - ∫(1)sin⁡tdt)dt]
= [-tcos⁡t + ∫cos⁡tdt]
= [-tcos⁡t + sin⁡t] + c
= -(tan^-1⁡x)/√(1 + x²) + x/√(1 + x²) + c
Hence, I = -(tan^-1⁡x)/√(1 + x²) + x/√(1 + x²) + c

Question 47. ∫ tan^-1(√x)dx

Solution:

Given that, I = ∫ tan^-1(√x)dx
Let us considered x = t²
dx = 2tdt
I = ∫2ttan^-1tdt
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
= 2[tan^-1)⁡t∫tdt - ∫(1/(1 + t²) ∫tdt)dt]
= 2[t²/2 tan^-1⁡t - ∫t²/2(1 + t²)dt]
= t² tan^-1⁡t - ∫(t² + 1 - 1)/(1 + t²)dt
= t² tan^-1⁡t - ∫(1 - 1/(1 + t²))dt
= t² tan^-1t - t + tan^-1⁡t + c
= (t² + 1) tan^-1⁡t - t + c
Hence, I = (x + 1)tan^-1⁡√x - √x + c

Question 48. ∫x³ tan^-1xdx

Solution:

Given that, I = ∫x³ tan^-1xdx
= tan^-1⁡x∫x³dx - (∫(dtan^-1⁡x)/dx (∫x³ dx)dx)
= tan^-1⁡x x⁴/4 - (∫1/(1 + x²) (x⁴/4)dx)
= tan^-1⁡x x⁴/4 - (∫1/(1 + x²) (x⁴/4)dx)
= tan^-1⁡x x⁴/4 - (∫1/(1 + x²) (x⁴/4)dx)
∫ 1/(1 + x²) (x⁴/4)dx = 1/4 [∫1/(1 + x²) dx + (x² - 1)dx]
∫ 1/(1 + x²) (x⁴/4)dx = 1/4 [tan^-1⁡x + x³/3 - x]
Hence, I = x⁴/4 tan^-1⁡x - 1/4 [tan^-1⁡x + x³/3 - x] + c

Question 49. ∫xsin⁡xcos⁡2xdx

Solution:

Given that, I = ∫xsin⁡xcos⁡2xdx
= 1/2 ∫x(2sin⁡xcos⁡2x)dx
= 1/2 ∫x(sin⁡(x + 2x) - sin⁡(2x - x))dx
= 1/2 ∫x(sin⁡3x - sin⁡x)dx
= 1/2[x](sin⁡3x - sin⁡x)dx - ∫ (1)(sin⁡3x - sin⁡x)dx)dx]
= 1/2 [x((-cos⁡3x)/3 + cos⁡x) - ∫(-(cos⁡3x)/3 + cos⁡x)dx]
Hence, I = 1/2 [-x (cos⁡3x)/3 + xcos⁡x + 1/9 sin⁡3x - sin⁡x] + c

Question 50. ∫(tan^-1x²)xdx

Solution:

Given that, I = ∫(tan^-1⁡x²)xdx
Let us considered x² = t
2xdx = dt
I = 1/2∫tan^-1tdt
= 1/2∫1tan^-1tdt
= 1/2 [tan^-1⁡t∫dt - (∫1/(1 + t²)∫dt)dt]
= 1/2 [t × tan^-1⁡t - ∫t/(1 + t²) dt]
= 1/2 t × tan^-1⁡t - 1/4∫2t/(1 + t²) dt
= 1/2 t × tan^-1⁡t - 1/4 log⁡|1 + t²| + c
Hence, I = 1/2 x² tan^-1⁡x² - 1/4 log⁡|1 + x⁴| + c

Question 51. ∫xdx/√(1 - x²)

Solution:

Given that, I = ∫xdx/√(1 - x²)
Let first function be sin^-1⁡x and second function be x/√(1 - x²).
Now, first we find the integral of the second function,
∫xdx/√(1 - x²)
Now, put t = 1 - x²
Then dt = -2xdx
Therefore,
∫ xdx/√(1 - x²) = -1/2 ∫dt/√t = -√t = -√(1 - x²)
Hence,
∫(xsin^-1x)/√(1 - x²) dx
= (sin^-1⁡x)(-√(1 - x²) - ∫1/√(1 - x²) * (-√(1 - x²))dx
= -√(1 - x²) sin^-1⁡x + x + c
= x - √(1 - x²) sin^-1⁡x + c

Question 52. ∫sin³√x dx

Solution:

Given that, I = ∫sin³√x dx
Let us considered √x = t
x = t²
dx = 2tdt
I = 2∫ tsin³⁡tdt
= 2∫t((3sin⁡t - sin⁡3t)/4)dt
= 1/2 ∫t(3sin⁡t - sin⁡3t)dt
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = 1/2 [t(-3cos⁡t + 1/3 cos⁡3t) - ∫(-3cos⁡t + (cos⁡3t)/3)dt]
= 1/2 [(-9tcos⁡t + tcos⁡3t)/3 - {-3sin⁡t + (sin⁡3t)/9}] + c
= 1/2 [(-9tcos⁡t + tcos⁡3t)/3 + (27sin⁡t - 3sin⁡3t)/9] + c
= 1/18[-27tcos⁡t + 3tcos⁡3t + 27sin⁡t - 3sin⁡3t] + c
Hence, I = 1/18[3√x cos⁡3√x + 27sin⁡√x - 27√x cos⁡√x - 3sin⁡3√x] + c

Question 53. ∫ xsin³xdx

Solution:

Given that, I = ∫ xsin³⁡xdx
= ∫x((3sin⁡x - sin⁡3x)/4)dx
= 1/4 ∫x(3sin⁡x - sin⁡3x)dx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
= 1/4 [x∫ (3sin⁡x - sin⁡3x)dx - ∫(1)(3sin⁡x - sin⁡3x)dx)dx]
= 1/4 [x(-3cos⁡x + (cos⁡3x)/3) - ∫(-3cos⁡x + (cos⁡3x)/3)dx]
= 1/4 [-3xcos⁡x + (xcos⁡3x)/3 + 3sin⁡x - (sin⁡3x)/9] + c
Hence, I = 1/36[3xcos⁡3x - 27xcos⁡x + 27sin⁡x - sin⁡3x] + c

Question 54. ∫cos³√x dx

Solution:

Given that, I = ∫cos³√x dx
Let us considered x = t²
dx = 2tdt
= 2∫tcos³⁡tdt
= 2∫t((3cos⁡t + cos⁡3t)/4)dt
= 1/2 ∫t(3cos⁡t + cos⁡3t)dt
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = 1/2 [t(3sin⁡t + 1/3 sin⁡3t) + ∫(1 × 3sin⁡t + (sin⁡3t)/3)dt]
= 1/2 [t((9sin⁡t + sin⁡3t)/3) + 3cos⁡t(cos⁡3t)/9] + c
= 1/18[27tsin⁡t + 3tsin⁡3t + 9cos⁡t + cos⁡3t] + c
Hence, I = 1/18[27√x sin⁡√x + 3√x sin⁡3√x + 9cos⁡√x + cos⁡3√x] + c

Question 55. ∫xcos³xdx

Solution:

Given that, I = ∫xcos³⁡xdx
= ∫x((3cos⁡x + cos⁡3x)/4)dx
= 1/4 ∫x(3cos⁡x + cos⁡3x)dx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = 1/4 [x∫(3cos⁡x + cos⁡3x)dx - ∫(1)(3cos⁡x + cos⁡3x)dx)dx]
= 1/4 [x(3sin⁡x + (sin⁡3x)/3) - ∫ (3sin⁡x + (sin⁡3x)/3)dx]
= 1/4 [3xsin⁡x + (xsin⁡3x)/3 + 3cos⁡x + (cos⁡3x)/9] + c
Hence, I = (3xsin⁡x)/4 + (xsin⁡3x)/12 + (3cos⁡x)/4 + (cos⁡3x)/36 + c

Question 56. ∫tan^-1√((1 - x)/(1 + x))

Solution:

Given that, I = ∫tan^-1√((1 - x)/(1 + x))
Let us considered x = cos⁡θ
dx = -sin⁡θdθ
I = ∫ tan^-1⁡(tan⁡θ/2)(-sin⁡θ)dθ
=-1/2 ∫θsin⁡θdθ
Let θ = u and sin⁡θdθ = v
So that sin⁡θ = ∫vdθ
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = -1/2 (-θcos⁡θ - ∫-cos⁡θdθ)
= -1/2(-θcos⁡θ + sin⁡θ)+c
= -1/2 (-θcos⁡θ + √(1 - cos²⁡θ)) + c
= -1/2 (-xcos^-1⁡x + √(1 - x²)) + c

Question 57. ∫sin^-1√(x/(a + x)) dx

Solution:

Given that, I = ∫sin^-1⁡√(x/(a + x)) dx
Let us considered x = atan²θ
dx = 2atan⁡θsec²⁡θdθ
I = ∫(sin^-1⁡√((atan²⁡θ)/(a + atan²⁡θ))(2atan⁡θsec²θ)dθ
= ∫ (sin^-1√((tan²θ)/(sec²θ)))(2atan⁡θsec²θ)dθ
= ∫ sin^-1(sin⁡θ)(2atan⁡θsec²θ)dθ
= ∫ 2θatan⁡θsec²θdθ
= 2a∣θ(tan⁡θsec²⁡θ)dθ)
= ∫2θatan⁡θsec²θdθ
= 2a∫θ(tan⁡θsec²⁡θ)dθ
= 2a[θ]tan⁡θsec²θdθ - ∫(∫tan⁡θsec²⁡θdθ)dθ]
= 2a[θ (tan²⁡θ)/2 - ∫(tan²θ)/2 dθ]
= aθtan²θ - 2a/2∫(sec²θ - 1)dθ
= aθtan²θ - atan⁡θ + aθ + c
= a(tan^-1⁡√(x/a)) x/a - a√(x/a) + atan^-1⁡√(x/a) + c
Hence, I = xtan^-1⁡√(x/a) - √ax + atan^-1⁡√(x/a) + c

Question 58. ∫(x³ sin^-1⁡x²)/√(1 - x⁴) dx

Solution:

Given that, I = ∫(x³ sin^-1x²)/√(1 - x⁴) dx
Let us considered sin^-1⁡x² = t
(1/√(1 - x⁴)(2x)dx = dt
I = ∫(x² sin^-1⁡x²)/√(1 - x⁴) xdx
= ∫(sin⁡t)t dt/2
= 1/2∫tsin⁡tdt
= 1/2 [t∫sin⁡tdt - ∫(1∫sin⁡tdt)dt]
= 1/2 [t(-cost)dt - ∫(1∫(-cost))dt]
= 1/2[-tcost + sint] + c
Hence, I = 1/2 [x² - √(1 - x⁴) sin^(-1)⁡x²] + c

Question 59. ∫(x² sin^-1⁡x)/(1 - x²)^3/2 dx

Solution:

Given that, I = ∫(x² sin^-1x)/(1 - x²)^3/2dx
Let us considered sin^-1⁡x = t
(1/√(1 - x²) dx = dt
I = ∫(sin²t × t)/((1 - sin²t)) dt
= ∫(tsin²t)/(cos²t) dt
= ∫t × tan²tdt
= ∫t(sec²⁡t - 1)dt
= ∫tsec²⁡tdt - t²/2 + c
= t∫sec²tdt - ∫(1∫sec²tdt)dt - t²/2 + c
= t × tan⁡t - ∫tan⁡tdt - t²/2 + c
= t × tan⁡t - log⁡sec⁡t - t²/2 + c
Hence, I = x/√(1 - x²) sin^-1x + log⁡|1 - x²| - 1/2 (sin^-1x)² + c

Question 60. ∫cos^-1(1 - x²/ 1 + x²) dx

Solution:

Given that, I = ∫cos^-1(1 - x²/ 1 + x²) dx
Let us considered, x = tant
dx = sec²tdt
I = ∫cos^-1(1 - tan²t/ 1 + tan²t) sec²tdt
= ∫ 2t sec²tdt
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = 2[t∫sec²tdt - ∫(1 ∫sec²tdt)dt]
= 2[t tan²t - ∫tant dt]
= 2[t tan²t - log sect] + c
= 2[x tan²x - log √1 + x²] + c
Hence, I = 2[xtan²x - log √1 + x²] + c

Summary

Exercise 19.25 | Set 3 typically deals with integrating rational functions where the denominator is of the form x⁴ + 1. The key points to remember are:

These integrals often require partial fraction decomposition.
The denominator x⁴ + 1 can be factored as (x² + √2x + 1)(x² - √2x + 1).
After partial fraction decomposition, you'll usually end up with terms of the form A/(x² + √2x + 1) and B/(x² - √2x + 1).
These terms can be integrated using the substitution method or by recognizing standard integral forms.

Class 12 RD Sharma Solutions - Chapter 19 Indefinite Integrals - Exercise 19.25 | Set 3

Evaluate the following integrals:

Question 41. ∫cos^-1⁡((1 - x²)/(1 + x²))dx

Question 42. ∫tan^-1⁡(2x/(1 - x²))dx

Question 43. ∫(x + 1)log⁡xdx

Question 44. ∫ x² tan^-1xdx

Question 45. ∫(e^logx+ sin⁡x) cos⁡xdx

Question 46. ∫((xtan^-1⁡x))/(1 + x²)^3/2 dx

Question 47. ∫ tan^-1(√x)dx

Question 48. ∫x³ tan^-1xdx

Question 49. ∫xsin⁡xcos⁡2xdx

Question 50. ∫(tan^-1x²)xdx

Question 51. ∫xdx/√(1 - x²)

Question 52. ∫sin³√x dx

Question 53. ∫ xsin³xdx

Question 54. ∫cos³√x dx

Question 55. ∫xcos³xdx

Question 56. ∫tan^-1√((1 - x)/(1 + x))

Question 57. ∫sin^-1√(x/(a + x)) dx

Question 58. ∫(x³ sin^-1⁡x²)/√(1 - x⁴) dx

Question 59. ∫(x² sin^-1⁡x)/(1 - x²)^3/2 dx

Question 60. ∫cos^-1(1 - x²/ 1 + x²) dx

Summary

Explore

Class 12 RD Sharma Solutions - Chapter 19 Indefinite Integrals - Exercise 19.25 | Set 3

Evaluate the following integrals:

Question 41. ∫cos-1⁡((1 - x2)/(1 + x2))dx

Question 42. ∫tan-1⁡(2x/(1 - x2))dx

Question 43. ∫(x + 1)log⁡xdx

Question 44. ∫ x2 tan-1xdx

Question 45. ∫(elogx + sin⁡x) cos⁡xdx

Question 46. ∫((xtan-1⁡x))/(1 + x2)3/2 dx

Question 47. ∫ tan-1(√x)dx

Question 48. ∫x3 tan-1xdx

Question 49. ∫xsin⁡xcos⁡2xdx

Question 50. ∫(tan-1x2)xdx

Question 51. ∫xdx/√(1 - x2)

Question 52. ∫sin3√x dx

Question 53. ∫ xsin3xdx

Question 54. ∫cos3√x dx

Question 55. ∫xcos3xdx

Question 56. ∫tan-1√((1 - x)/(1 + x))

Question 57. ∫sin-1√(x/(a + x)) dx

Question 58. ∫(x3 sin-1⁡x²)/√(1 - x4) dx

Question 59. ∫(x2 sin-1⁡x)/(1 - x2)3/2 dx

Question 60. ∫cos-1(1 - x2/ 1 + x2) dx

Summary

Explore

Question 41. ∫cos^-1⁡((1 - x²)/(1 + x²))dx

Question 42. ∫tan^-1⁡(2x/(1 - x²))dx

Question 44. ∫ x² tan^-1xdx

Question 45. ∫(e^logx+ sin⁡x) cos⁡xdx

Question 46. ∫((xtan^-1⁡x))/(1 + x²)^3/2 dx

Question 47. ∫ tan^-1(√x)dx

Question 48. ∫x³ tan^-1xdx

Question 50. ∫(tan^-1x²)xdx

Question 51. ∫xdx/√(1 - x²)

Question 52. ∫sin³√x dx

Question 53. ∫ xsin³xdx

Question 54. ∫cos³√x dx

Question 55. ∫xcos³xdx

Question 56. ∫tan^-1√((1 - x)/(1 + x))

Question 57. ∫sin^-1√(x/(a + x)) dx

Question 58. ∫(x³ sin^-1⁡x²)/√(1 - x⁴) dx

Question 59. ∫(x² sin^-1⁡x)/(1 - x²)^3/2 dx

Question 60. ∫cos^-1(1 - x²/ 1 + x²) dx