Question 16

NUMERICALHARD

Intersection Points and Enclosed Area of Exponential-Trigonometric Curves

Consider the curve $C_1$ given by $y = e^{-x} \text{ for } x \in [0, 10\pi],$ and the curve $C_2$ given by $y = e^{-x}(\sin x + \cos x) \text{ for } x \in [0, 10\pi].$ Let $n$ be the total number of points of intersection of the curves $C_1$ and $C_2$ . Suppose that $\alpha_1, \alpha_2, \dots, \alpha_n \in [0, 10\pi]$ are the $x$ -coordinates of the points of intersection of the curves $C_1$ and $C_2$ such that $\alpha_1 < \alpha_2 < \dots < \alpha_n$ .

Let $\beta$ be the area of the region enclosed between the curves $C_1, C_2$ , and the lines $x = \alpha_1$ and $x = \alpha_4$ . Then the value of $-\frac{1}{\pi} \log_e \left( \beta - 2e^{-\frac{\pi}{2}} \right)$ is

Correct Answer: 2.5

Detailed Solution

From the previous question, $\alpha_1 = 0$ , $\alpha_2 = \frac{\pi}{2}$ , $\alpha_3 = 2\pi$ , and $\alpha_4 = \frac{5\pi}{2}$ .

The area $\beta$ is given by:

$\beta = \int_{\alpha_1}^{\alpha_4} |e^{-x} - e^{-x}(\sin x + \cos x)| dx = \int_{0}^{5\pi/2} e^{-x} |1 - (\sin x + \cos x)| dx$

In $[0, \pi/2]$ , $\sin x + \cos x \ge 1$ . In $[\pi/2, 2\pi]$ , $\sin x + \cos x \le 1$ . In $[2\pi, 5\pi/2]$ , $\sin x + \cos x \ge 1$ .

Let $J(x) = \int e^{-x}(\sin x + \cos x - 1) dx = e^{-x}(1 - \cos x)$ .

$\beta = [J(x)]_{0}^{\pi/2} + [-J(x)]_{\pi/2}^{2\pi} + [J(x)]_{2\pi}^{5\pi/2}$

$J(0) = 0$

$J(\frac{\pi}{2}) = e^{-\pi/2}$

$J(2\pi) = 0$

$J(\frac{5\pi}{2}) = e^{-5\pi/2}$

$\beta = (e^{-\pi/2} - 0) - (0 - e^{-\pi/2}) + (e^{-5\pi/2} - 0) = 2e^{-\pi/2} + e^{-5\pi/2}$

We need to find the value of:

$-\frac{1}{\pi} \log_e (\beta - 2e^{-\pi/2}) = -\frac{1}{\pi} \log_e (e^{-5\pi/2}) = -\frac{1}{\pi} \left( -\frac{5\pi}{2} \right) = 2.5$ .

Question 16

Intersection Points and Enclosed Area of Exponential-Trigonometric Curves

Detailed Solution

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