`int_(0)^(pi//2) e^(x) (sin x + cos x) dx`

`int_(0)^(pi//2) e^(x) (sin x + cos x) dx`
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`int_(0)^(pi//2) e^(x) (sin x + cos x) dx`
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`int_(0)^(pi//2) sqrt(1- cos 2x) dx`

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`int_(0)^(pi//6) sqrt(1-sin 2x) dx`

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\( Q: \int_{\frac{5 \pi}{4}}^{\frac{3 \pi}{2}} \frac{\frac{x}{x}-\frac{x \cdot x}{2}+\frac{(x 2)^{2}}{24}-\frac{x^{4} x 2}{720}+\cdots \infty}{\sqrt{\frac{1-\cos 2 x}{8}}} \)

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`int_(0)^(pi//4) sqrt(cot x dx) =?`

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`int_(0)^(pi//4) log (1+tan x) dx =?`

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`int_(0)^(pi) (1-x^(2))/((1+x^(2))^(2))dx`

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Last Answer : `int_(0)^(pi) (1-x^(2))/((1+x^(2))^(2))dx`

`int_(0)^(pi) (1-x^(2))/((1+x^(2))^(2))dx`

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Last Answer : `int_(0)^(pi) (1-x^(2))/((1+x^(2))^(2))dx`

`int_(0)^(pi//4) tan x dx`

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`int_(0)^(1//2) (x sin^(-1)x)/(sqrt(1-x^(2)))dx=?`

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Last Answer : `int_(0)^(1//2) (x sin^(-1)x)/(sqrt(1-x^(2)))dx=?` A. `(pi sqrt(3))/(12)+(1)/(2)` B. `(pisqrt(3))/(12)-(1)/(2)` C. `(pisqrt(3))/(12) -(1)/(2)` D.

`int_(0)^(1//sqrt(2)) (sin^(-1))/((1-x^(2))^(3//2))dx`

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`int_(0)^(1) (x sin^(-1)x)/(sqrt(1+2x)^(2))dx`

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No. of solutions of `16^(sin^2x)+16^(cos^2x)=10, 0 le x le 2 pi` is

Description : No. of solutions of `16^(sin^2x)+16^(cos^2x)=10, 0 le x le 2 pi` is

Last Answer : No. of solutions of `16^(sin^2x)+16^(cos^2x)=10, 0 le x le 2 pi` is

`int_(a)^(b)cos x dx`

Description : `int_(a)^(b)cos x dx`

Last Answer : `int_(a)^(b)cos x dx`

`int_(pi//6)^(pi//2) (" cosec x cot x")/(1+" cosec "^(2) x)dx`

Description : `int_(pi//6)^(pi//2) (" cosec x cot x")/(1+" cosec "^(2) x)dx`

Last Answer : `int_(pi//6)^(pi//2) (" cosec x cot x")/(1+" cosec "^(2) x)dx`

`int_(-pi//4)^(pi//4) "cosec"^(2) x dx`

Description : `int_(-pi//4)^(pi//4) "cosec"^(2) x dx`

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According to D' Alembert's principle, m (d 2 x/ dt 2 ) + c (dx/dt) + Kx =0 is the differential equation for damped free vibrations having single degree of freedom. What will be the solution to this differential equation if the system is critically damped? A x = (A + Bt) e – ωt B x = X e – ξωt (sin ω d t + Φ) C x = (A – Bt) e – ωt D x = X e – ξωt (cos ω d t + Φ)

Description : According to D' Alembert's principle, m (d 2 x/ dt 2 ) + c (dx/dt) + Kx =0 is the differential equation for damped free vibrations having single degree of freedom. What will be the solution to this differential equation if the system is ... Φ) C x = (A - Bt) e - ωt D x = X e - ξωt (cos ω d t + Φ)

Last Answer : A x = (A + Bt) e – ωt

According to D' Alembert's principle, m (d 2 x/ dt 2 ) + c (dx/dt) + Kx =0 is the differential equation for damped free vibrations having single degree of freedom. What will be the solution to this differential equation if the system is critically damped? A. x = (A + Bt) e – ωt B. x = X e – ξωt (sin ω d t + Φ) C. x = (A – Bt) e – ωt D. x = X e – ξωt (cos ω d t + Φ

Description : According to D' Alembert's principle, m (d 2 x/ dt 2 ) + c (dx/dt) + Kx =0 is the differential equation for damped free vibrations having single degree of freedom. What will be the solution to this differential equation if the system is ... ) C. x = (A - Bt) e - ωt D. x = X e - ξωt (cos ω d t + Φ

Last Answer : A. x = (A + Bt) e – ωt

According to D' Alembert's principle, m (d 2 x/ dt 2 ) + c (dx/dt) + Kx =0 is the A differential equation for damped free vibrations having single degree of freedom. What will be the solution to this differential equation if the system is critically damped? ( A ) x = (A + Bt) e – ωt (B)x = X e – ξωt (sin ω d t + Φ) (C)x = (A – Bt) e – ωt ( D )x = X e – ξωt (cos ω d t + Φ

Description : According to D' Alembert's principle, m (d 2 x/ dt 2 ) + c (dx/dt) + Kx =0 is the A differential equation for damped free vibrations having single degree of freedom. What will be the solution to this differential equation if the system is ... (C)x = (A - Bt) e - ωt ( D )x = X e - ξωt (cos ω d t + Φ

Last Answer : ( A ) x = (A + Bt) e – ωt

According to D' Alembert's principle, m (d 2 x/ dt 2 ) + c (dx/dt) + Kx =0 is the differential equati damped free vibrations having single degree of freedom. What will be the solution to this differ equation if the system is critically damped? a. x = (A + Bt) e – ωt b. x = X e – ξωt (sin ω d t + Φ) c. x = (A – Bt) e – ωt d. x = X e – ξωt (cos ω d t + Φ)

Description : According to D' Alembert's principle, m (d 2 x/ dt 2 ) + c (dx/dt) + Kx =0 is the differential equati damped free vibrations having single degree of freedom. What will be the solution to this differ equation if the system is critically ... c. x = (A - Bt) e - ωt d. x = X e - ξωt (cos ω d t + Φ)

Last Answer : a. x = (A + Bt) e – ωt