Use integration by parts to evaluate the integral: ∫ e^8r sin ( − 3r )dr

Evaluate the integral using integration by parts with the indicated choices of u and dv. (Use...

Evaluate the integral using integration by parts with the indicated choices of u and dv. (Use C for the constant of integration.) xe5xdx;    u = x,  dv = e5xdx 2. Evaluate the integral. (Use C for the constant of integration.) (x2 + 10x) cos(x) dx 3. Evaluate the integral. (Use C for the constant of integration.) cos−1(x) dx 4. Evaluate the integral. (Use C for the constant of integration.) ln( x ) dx

Use integration by parts to evaluate the integral: ∫9xcos(−2x)dx

Use integration by parts to evaluate the integral: ∫9xcos(−2x)dx

1. ∫3xe^4x dx = 2. Use integration by parts to evaluate the integral: ∫2s cos(s)ds

1. ∫3xe^4x dx = 2. Use integration by parts to evaluate the integral: ∫2s cos(s)ds

Use Romberg integration to evaluate the integral of e^(-x^2 ) between the limits a=1 and b=2.5....

Use Romberg integration to evaluate the integral of e^(-x^2 ) between the limits a=1 and b=2.5. Use the initial h=b-a. Find the integral to an error of order O(h^6).

Find this integral using Integration By Parts; use the Tabular D.I. method. ∫ e^(5x) cos x...

Find this integral using Integration By Parts; use the Tabular D.I. method. ∫ e^(5x) cos x dx

Sketch the region of integration. 3 0 3 sin x2dx dy y Evaluate the iterated integral....

Sketch the region of integration. 3 0 3 sin x2dx dy y Evaluate the iterated integral. (Hint: Note that it is necessary to switch the order of integration. Round your answer to four decimal places.) 3 0 3 sin x2dx dy y = 0 sin x2dy dx ≈ 0

For the following integral Sketch the region of integration. Reverse the order of integration. Evaluate the...

For the following integral Sketch the region of integration. Reverse the order of integration. Evaluate the integral in (b) 04y22ex2dxdy

Question B:Consider the integral of sin(x) * cos(x) dx. i) Do it using integration by parts;...

Question B:Consider the integral of sin(x) * cos(x) dx. i) Do it using integration by parts; you might need the “break out of the loop” trick. I would do u=sin(x), dv=cos(x)dx ii) Do it using u-substitution. I would do u=cos(x) iii) Do it using the identity sin(x)*cos(x)=0.5*sin(2x) iv) Explain how your results in parts i,ii,iii relate to each other.

evaluate the double integral x^2 y da, r is 9x^2+4y^2=36, use x=2u and y=3r

evaluate the double integral x^2 y da, r is 9x^2+4y^2=36, use x=2u and y=3r

Use integration by parts to evaluate the following integrals: (a)? ∫x ln xdx (b)? ∫ x^2...

Use integration by parts to evaluate the following integrals: (a)? ∫x ln xdx (b)? ∫ x^2 e^4x dx