Evaluate using Special Integral Forms MCQ Quiz in తెలుగు - Objective Question with Answer for Evaluate using Special Integral Forms - ముఫ్త్ [PDF] డౌన్లోడ్ కరెన్
Last updated on Apr 8, 2025
Latest Evaluate using Special Integral Forms MCQ Objective Questions
Top Evaluate using Special Integral Forms MCQ Objective Questions
Evaluate using Special Integral Forms Question 1:
The value of \(\int_{-1}^1\left|\tan ^{-1} x\right| d x\) is:
Answer (Detailed Solution Below)
Evaluate using Special Integral Forms Question 1 Detailed Solution
Calculation:
We are given the function:
I = ∫-11 |tan-1(x)| dx
Step 1: Split the integral based on the absolute value:
I = ∫-10 -tan-1(x) dx + ∫01 tan-1(x) dx
Step 2: Use the standard result for the integral of tan-1(x):
∫ tan-1(x) dx = x tan-1(x) - 1/2 ln(1 + x2)
Step 3: Compute each integral:
For ∫-10 -tan-1(x) dx, we get:
- [ x tan-1(x) - 1/2 ln(1 + x2) ]-10
At x = 0, the expression becomes 0.
At x = -1, we get:
- [-1 × (-π/4) - 1/2 ln(1 + 1)] = π/4 - 1/2 ln(2)
Thus, the value of the first integral is:
π/4 - 1/2 ln(2)
For ∫01 tan-1(x) dx, we use the same result:
[ x tan-1(x) - 1/2 ln(1 + x2) ]01
At x = 1, the expression becomes:
1 × (π/4) - 1/2 ln(2) = π/4 - 1/2 ln(2)
At x = 0, the expression is 0.
Thus, the value of the second integral is:
π/4 - 1/2 ln(2)
Step 4: Add the results of the two integrals:
I = (π/4 - 1/2 ln(2)) + (π/4 - 1/2 ln(2)) = π/2 - ln(2)
∴ The value of the integral is π/2 - ln(2).
The correct answer is Option (1): π/2 - ln(2)
Evaluate using Special Integral Forms Question 2:
Let \(\rm \beta(m,n)=\int_0^1x^{m-1}(1-x)^{n-1}dx\) m, n > 0 If \(\rm \int_0^1(1-x^{10})^{20}dx=a\times \beta (b,c)\) then 100 (a + b + c) equals ______.
Answer (Detailed Solution Below)
Evaluate using Special Integral Forms Question 2 Detailed Solution
Calculation:
Given, \(\rm \beta(m,n)=\int_0^1x^{m-1}(1-x)^{n-1}dx\)
Let I = \(\int_0^1 1 \cdot\left(1-x^{10}\right)^{20} d x\)
Put x10 = t ⇒ x = t1/10
⇒ \(\mathrm{dx}=\frac{1}{10}(\mathrm{t})^{-9 / 10} \mathrm{dt}\)
∴ I = \(\int_0^1(1-t)^{20} \frac{1}{10}(t)^{-9 / 10} d t\)
⇒ I = \(\frac{1}{10} \int_0^1 t^{-9 / 10}(1-t)^{20} d t\)
= \(\frac{1}{10} \int_0^1 x^{-9 / 10}(1-x)^{20} d x\)
= \(\rm \frac{1}{10}\times \beta (\frac{1}{10},21)\) = \(\rm a\times \beta (b,c)\)
⇒ a = \(\frac{1}{10}\) b = \(\frac{1}{10}\) c = 21
⇒ 100(a + b + c) = 100(\(\frac{1}{10}\) + \(\frac{1}{10}\) + 21) = 10 + 10 + 2100 = 2120
∴ The value of 100(a + b + c) is 2120.
The correct answer is Option 4.
Evaluate using Special Integral Forms Question 3:
What is the value of \(\rm \int e^x \left(\dfrac{1}{x}- \dfrac{1}{x^2}\right)dx \)
Answer (Detailed Solution Below)
Evaluate using Special Integral Forms Question 3 Detailed Solution
Concept
\(\rm \int e^x \left(f(x)+f'(x)\right)dx \) = ex f(x) + c
Calculation:
Let, \(\rm I=\int e^x \left(\dfrac{1}{x}- \dfrac{1}{x^2}\right)dx \)
Let f(x) = \(\rm 1\over x\)
⇒ \(\rm f'(x) = - {1\over x^2}\)
∴ \(\rm I=\int e^x \left(\dfrac{1}{x}- \dfrac{1}{x^2}\right)dx \)= \(\rm \int e^x \left(f(x)+f'(x)\right)dx \)
= ex f(x) + c
= \(\rm e^x ({1\over x})\) + c
Hence, option (3) is correct.