Solve the following integrals: 1. The integral of 2 (on top) to 0 (on bottom) of...

a). Find dy/dx for the following integral. y=Integral from 0 to cosine(x) dt/√1+ t^2 , 0<x<pi  ...

a). Find dy/dx for the following integral. y=Integral from 0 to cosine(x) dt/√1+ t^2 , 0<x<pi   b). Find dy/dx for tthe following integral y=Integral from 0 to sine^-1 (x) cosine t dt

Explain whether the following integrals converge or not. If the integral converges, find the value. If...

Explain whether the following integrals converge or not. If the integral converges, find the value. If the integral does not converge, describe why (does it go to +infinity, -infinity, oscillate, ?) i) Integral from x=1 to x=infinity of x^-1.4 dx ii) Integral from x=1 to x=infinity of 1/x^2 * (sin x)^2 dx iii) Integral from x=0 to x=1 of 1/(1-x) dx

(1 point) Let F(x)=∫o,x sin(6t^2) dt F(x)=∫0xsin⁡(6t^2) dt. The integrals go from 0 to x Find...

(1 point) Let F(x)=∫o,x sin(6t^2) dt F(x)=∫0xsin⁡(6t^2) dt. The integrals go from 0 to x Find the MacLaurin polynomial of degree 7 for F(x)F(x). Use this polynomial to estimate the value of ∫0, .790 sin(6x^2) dx ∫0, 0.79 sin⁡(6x^2) dx. the integral go from 0 to .790

1. Evaluate the definite integral given below. ∫(from 0 to π/3) (2sin(x)+3cos(x)) dx 2. Given F(x)...

1. Evaluate the definite integral given below. ∫(from 0 to π/3) (2sin(x)+3cos(x)) dx 2. Given F(x) below, find F′(x). F(x)=∫(from 2 to ln(x)) (t^2+9)dt 3. Evaluate the definite integral given below. ∫(from 0 to 2) (−5x^3/4 + 2x^1/4)dx

1. the integral of 0 to 1 of (x) / (2x+1)^3 dx 2. the integral of...

1. the integral of 0 to 1 of (x) / (2x+1)^3 dx 2. the integral of 2 to 4 of (x+2) / (x^2+3x-4) dx

1. Find the partial fraction decomposition of the rational function: (2s − 4)/(s^2 + s)(s^2 +...

1. Find the partial fraction decomposition of the rational function: (2s − 4)/(s^2 + s)(s^2 + 1) 2. Find: ∫ (9x)/(sqrt. root(25-x^2)) dx +  ∫ (3)/(sqrt. root(25-x^2)) dx (use C for constant of integration). 3. Evaluate the following integral: ∫ 17t sin^2(t) dt

Evaluate the following integral: 1. ∫xsec(square)xdx 2. ∫e(power)t{root(1+e(power)2t)}dt

Evaluate the following integral: 1. ∫xsec(square)xdx 2. ∫e(power)t{root(1+e(power)2t)}dt

Consider the sum of double integrals Z1 1/√2Zx √1−x2 xy dy dx +Z√2 1 Zx 0...

Consider the sum of double integrals Z1 1/√2Zx √1−x2 xy dy dx +Z√2 1 Zx 0 xy dy dx +Z2 √2Z√4−x2 0 xy dy dx . a. [4] Combine into one integral and describe the domain of integration in terms of polar coordinates. Give the range for the radius r. b. [4] Compute the integral.

The integral ∫-1(bottom) to 0 ∫sqrt(−1−x2)(bottom) to 0 −4/(−5+sqrt(x^2+y^2)dydx is very hard to do. If you...

The integral ∫-1(bottom) to 0 ∫sqrt(−1−x2)(bottom) to 0 −4/(−5+sqrt(x^2+y^2)dydx is very hard to do. If you put it in polar form it's much easier, ∫ba∫dc f(r,θ)r drdθ it's much easier, but you need to work out the new limits. Find a,b,c,d and the value of the integral. a= b= c= d= ∫-1(bottom) to 0∫-sqrt(1−x^2)(bottom) to 0 a/(b+sqrt(x^2+y^2)dydx=

a) A fluid flows from the top of a cylinder to the bottom through a hole....

a) A fluid flows from the top of a cylinder to the bottom through a hole. Given Bernoulli's equation and that the fluid's level is at height y(t) in a cylinder, derive the form dy/dt = −f(y). For Bernoulli’s equation, the kinetic energy term of the fluid’s top surface can be considered zero. b) The previous differential equation may be integrated as integral from 0 to ∆t dt = integral from 0 to h0 of (1/f(y)) dy. Use this to...