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

Evaluate the following integrals:

Question 1. ∫x cos⁡xdx

Solution:

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

Question 2. ∫log⁡(x + 1)dx

Solution:

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

Question 3. ∫x³ log⁡xdx

Solution:

Given that, I = ∫ x³ log⁡xdx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = log⁡x ∫x³ dx - ∫(1/x × ∫x³ dx)dx + c
= x⁴/4 log⁡x - ∫x⁴/4x dx+c
= x⁴/4 log⁡x - 1/4∫x³ dx + c
= x⁴/4 log⁡x - 1/4 ∫x⁴/4 dx + c
I = x⁴/4 log⁡x - 1/16 x⁴+ c

Question 4. ∫xe^x dx

Solution:

Given that I = ∫xe^x dx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = xe^x- ∫1.e^x dx
= xe^x- e^x+ c
Hence, I = = xe^x- e^x+ c

Question 5. ∫xe^2x dx

Solution:

Given that, I = ∫xe^2x dx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = x∫e^2x dx - ∫(1 × ∫ e^2x dx) dx + c
= x∫e^2xdx - ∫(1 × ∫e^2x dx)dx + c
= (xe^2x)/2 - ∫(e^2x/2)dx + c
= (xe^2x)/2 - e^2x/4 + c
Hence, I = (x/2 - 1/4) e^2x+ c

Question 6. ∫x² e^-x dx

Solution:

Given that I = ∫x² e^-x dx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = x² ∫e^-x dx - ∫(2x∫e^-x dx)dx
= -x² e^-x- ∫(2x)(-e^-x)dx
= -x² e^-x+ 2∫xe^-x dx
= -x² e^-x+ 2[x∫e^-x dx - ∫(1 × ∫ e^-x dx) dx]
= -x² e^-x+ 2[x(-e^-x) - ∫(-e^-x)dx]
= -x² e^-x- 2xe^-x+ 2∫e^-x dx
Hence, I = -x² e^-x- 2xe^-x- 2e^-x+ c

Question 7. ∫ x²cos⁡xdx

Solution:

Given that, I = ∫ x²cos⁡xdx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = x² ∫ cos⁡xdx - ∫(2x)cos⁡xdx)dx
= x² sin⁡x - 2∫(x)(sin⁡x)dx
= x² sin⁡x - 2[x∫sin⁡xdx - ∫(1 × ∫sin⁡xdx)dx]
= x² sin⁡x - 2[x(-cos⁡x) - ∫(-cos⁡x)dx]
= x² sin⁡x + 2xcos⁡x - 2∫(cos⁡x)dx
Hence, I = x²sin⁡x + 2xcos⁡x - 2sin⁡x + c

Question 8. ∫x²cos⁡2xdx

Solution:

Given that, I = ∫x²cos⁡2xdx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = x² ∫cos⁡2xdx - ∫(2x∫ cos⁡2xdx)dx
= x² (sin⁡2x)/2 - 2∫x((sin⁡2x)/2)dx
= 1/2 x² sin⁡2x - ∫xsin⁡2xdx
= 1/2 x² sin⁡2x - [x∫sin⁡2xdx - ∫ (1∫ sin⁡2xdx)dx]
= 1/2 x² sin⁡2x - [x((-cos⁡2x)/2) - ∫(-(cos⁡2x)/2)dx]
= 1/2 x²sin⁡2x + x/2 cos⁡2x - 1/2 ∫(cos⁡2x)dx
Hence, I = 1/2 x² sin⁡2x + x/2 cos⁡2x - 1/4 sin⁡2x + c

Question 9. ∫xsin⁡2xdx

Solution:

Given that, I =∫xsin⁡2xdx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = x∫sin⁡2xdx - ∫(1)sin⁡2xdx)dx
= x(-(cos⁡2x)/2) - ∫(-(cos⁡2x)/2)dx
= -x/2 cos⁡2x + 1/2 ∫cos⁡2xdx
= -x/2 cos⁡2x + 1/2(sin⁡2x)/2 + c
Hence, I = -x/2 cos⁡2x + 1/4 sin⁡2x + c

Question 10. ∫(log⁡(log⁡x))/x dx

Solution:

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

Question 11. ∫x² cos⁡xdx

Solution:

Given that I = ∫x²cos⁡xdx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = x²∫ cos⁡xdx - ∫(2x]cos⁡xdx)dx
= x²sin⁡x - 2∫xsin⁡xdx
= x² sin⁡x - 2[x∫sin⁡xdx - ∫(1]sin⁡xdx)dx]
= x² sin⁡x - 2[x(-cos⁡x) - ∫(-cos⁡x)dx]
= x² sin⁡x + 2xcos⁡x - 2∫(cos⁡x)dx
Hence, I = x² sin⁡x + 2xcos⁡x - 2sin⁡x + c

Question 12. ∫xcosec²⁡xdx

Solution :

Given that, I = ∫xcosec²⁡xdx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = x∫cosec²xdx - ∫(∫ cosec²xdx)dx
= -xcot⁡x + ∫cot⁡xdx
= -x cot⁡x + log ⁡|sin⁡x| + c
Hence, I = -x cot⁡x + log ⁡|sin⁡x| + c

Question 13. ∫xcos²xdx

Solution:

Given that, I = ∫xcos²xdx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = x∫cos²⁡xdx - ∫(1∫ cos²xdx)dx
= x∫((cos⁡2x + 1)/2)dx - ∫(∫((1 + cos⁡2x)/2)dx)dx
= x/2 [(sin⁡2x)/2 + x] - 1/2∫(x + (sin⁡2x)/2)dx
= x/4 sin⁡2x + x²/2 - 1/2 × x²/2 - 1/4 (-(cos⁡2x)/2) + c
Hence, I = x/4 sin⁡2x + x²/4 + 1/8 cos⁡2x + c

Question 14. ∫xⁿ log⁡x dx

Solution:

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

Question 15. ∫(log⁡x)/xⁿ dx

Solution:

Given that, I = ∫(log⁡x)/xⁿdx = ∫(log⁡x)(1/xⁿ)dx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
I = log⁡x∫(1/xⁿ)dx - ∫((d(log⁡x))/dx)(∫(1/xⁿ)dx)dx
= log⁡x(x^1-n/(1 - n)) - ∫1/x (x^1-n/(1 - n))dx
= log⁡x(x^1-n/(1 - n)) - ∫(xⁿ/(1 - n))dx
= log⁡x(x^1-n/(1 - n)) - (1/(1 - n))(x^1-n/(1 - n))
Hence, I = log⁡x(x^1-n/(1 - n)) - (x^1-n/([1 - n]²)) + c

Question 16. ∫x² sin²⁡xdx

Solution:

Given that, I = ∫x² sin²⁡xdx
= ∫x² ((1 - cos⁡2x)/2)dx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
= ∫x²/2 dx - ∫((x² cos⁡2x)/2)dx
= x³/6 - 1/2 [∫x² cos⁡2xdx]
= x³/6 - 1/2 [x² ∫cos⁡2xdx - ∫ (2x∫cos⁡2xdx)dx]
= x³/6 - 1/2 (x²(sin⁡2x)/2) + 1/2 × 2∫(x (sin⁡2x)/2)dx
= x³/6 - 1/4 x²sin⁡2x + 1/2 [x ∫sin⁡2xdx - ∫(1∫sin⁡2xdx)dx]
= x³/6 - 1/4 x² sin⁡2x + 1/2 [x(-(cos⁡2x)/2) - ∫(-(cos⁡2x)/2)dx]
= x³/6 - 1/4 x² sin⁡2x + 1/2 x(-(cos⁡2x)/2) + 1/4 × (sin2x/2) + c
= x³/6 - 1/4 x² sin⁡2x - 1/4 x(cos⁡2x) + 1/8 × (sin2x) + c
Hence, I = x³/6 - 1/4 x² sin⁡2x - 1/4 x(cos⁡2x) + 1/8 × (sin2x) + c

Question 17. ∫2x^3 e^{x^2} xdx

Solution:

Given that, l = ∫2x^3 e^{x^2} xdx
Let us assume, x² = t
2xdx = dt
I = ∫t × e^t dt
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
= t∫e^t dt - ∫(1 × ∫e^tdt)dt
= te^t- ∫e^t dt
= te^t- e^t+ c
= e^t-1+ c
Hence, I = e^{x^2} (x² - 1) + c

Question 18. ∫x³ cos⁡x² dx

Solution:

Given that, I = ∫x³ cos⁡x² dx
Let us assume x²= t
2xdx = dt
I = 1/2 ∫tcos⁡tdt
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
= 1/2[t∫cos⁡tdt - ∫(1 × ∫cos⁡tdt)dt]
= 1/2 [t × sin⁡t - ∫sin⁡tdt]
= 1/2[tsin⁡t + cos⁡t] + c
Hence, I = 1/2 [x² sin⁡x²+ cos⁡x²] + c

Question 19. ∫xsin⁡xcos⁡xdx

Solution:

Given that, I = ∫xsin⁡xcos⁡xdx
= ∫x/2(2sin⁡xcos⁡x)dx
= 1/2 ∫xsin⁡2xdx
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
= 1/2 [x∫sin⁡2xdx - ∫(1 × ∫sin⁡2xdx)dx]
= 1/2 [x((-cos⁡2x)/2) - ∫((-cos⁡2x)/2)dx]
= -1/4 xcos⁡2x + 1/4 ∫cos⁡2xdx
Hence, I = -1/4 xcos⁡2x + 1/8 sin⁡2x + c

Question 20. ∫sin⁡x(log⁡cos⁡x)dx

Solution:

Given that, I = ∫sin⁡x(log⁡cos⁡x)dx
Let us considered, cos⁡x = t
-sin⁡xdx = dt
I = -∫ log⁡tdt
= -∫1 × log⁡tdt
Using integration by parts,
∫u v dx = v∫ u dx - ∫{d/dx(v) × ∫u dx}dx + c
We get
= -[log⁡t∫dt - ∫(1/t × ∫dt)dt]
= -[tlog⁡t - ∫1/t × tdt]
= -[tlog⁡t-∫ dt]
= -[tlog⁡t - t + c₁ ]
= t(1 - logt) + c
Hence, I = cosx(1 - logcosx) + c

Summary

Exercise 19.25 | Set 1 typically deals with integrating rational functions where the denominator is of the form 1 ± x⁴. Key points to remember:

These integrals often require partial fraction decomposition.

For 1 - x⁴, it can be factored as (1 - x²)(1 + x²) or (1 - x)(1 + x)(1 + x²).
For 1 + x⁴, it can be factored as (1 + x²)² - (√2x)² = (1 + √2x + x²)(1 - √2x + x²).
After partial fraction decomposition, you'll usually end up with simpler rational terms.
These terms can be integrated using standard integration techniques or by recognizing standard forms.

Class 12 RD Sharma Solutions - Chapter 19 Indefinite Integrals - Exercise 19.25 | Set 1

Evaluate the following integrals:

Question 1. ∫x cos⁡xdx

Question 2. ∫log⁡(x + 1)dx

Question 3. ∫x³ log⁡xdx

Question 4. ∫xe^x dx

Question 5. ∫xe^2x dx

Question 6. ∫x² e^-x dx

Question 7. ∫ x²cos⁡xdx

Question 8. ∫x²cos⁡2xdx

Question 9. ∫xsin⁡2xdx

Question 10. ∫(log⁡(log⁡x))/x dx

Question 11. ∫x² cos⁡xdx

Question 12. ∫xcosec²⁡xdx

Question 13. ∫xcos²xdx

Question 14. ∫xⁿ log⁡x dx

Question 15. ∫(log⁡x)/xⁿ dx

Question 16. ∫x² sin²⁡xdx

Question 17. ∫2x^3 e^{x^2} xdx

Question 18. ∫x³ cos⁡x² dx

Question 19. ∫xsin⁡xcos⁡xdx

Question 20. ∫sin⁡x(log⁡cos⁡x)dx

Summary

Explore

Class 12 RD Sharma Solutions - Chapter 19 Indefinite Integrals - Exercise 19.25 | Set 1

Evaluate the following integrals:

Question 1. ∫x cos⁡xdx

Question 2. ∫log⁡(x + 1)dx

Question 3. ∫x3 log⁡xdx

Question 4. ∫xex dx

Question 5. ∫xe2x dx

Question 6. ∫x2 e-x dx

Question 7. ∫ x2cos⁡xdx

Question 8. ∫x2cos⁡2xdx

Question 9. ∫xsin⁡2xdx

Question 10. ∫(log⁡(log⁡x))/x dx

Question 11. ∫x2 cos⁡xdx

Question 12. ∫xcosec2⁡xdx

Question 13. ∫xcos2xdx

Question 14. ∫xn log⁡x dx

Question 15. ∫(log⁡x)/xn dx

Question 16. ∫x2 sin2⁡xdx

Question 17. ∫2x^3 e^{x^2} xdx

Question 18. ∫x3 cos⁡x2 dx

Question 19. ∫xsin⁡xcos⁡xdx

Question 20. ∫sin⁡x(log⁡cos⁡x)dx

Summary

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Question 3. ∫x³ log⁡xdx

Question 4. ∫xe^x dx

Question 5. ∫xe^2x dx

Question 6. ∫x² e^-x dx

Question 7. ∫ x²cos⁡xdx

Question 8. ∫x²cos⁡2xdx

Question 11. ∫x² cos⁡xdx

Question 12. ∫xcosec²⁡xdx

Question 13. ∫xcos²xdx

Question 14. ∫xⁿ log⁡x dx

Question 15. ∫(log⁡x)/xⁿ dx

Question 16. ∫x² sin²⁡xdx

Question 18. ∫x³ cos⁡x² dx