Solve the following equation in the interval [0, 2 π]. Note: Give the answer as a...

a. Find the critical numbers of the function on the interval ( 0 , 2 π...

a. Find the critical numbers of the function on the interval ( 0 , 2 π ) . (Enter your answers as a comma-separated list. If an answer does not exist, enter DNE.) g(θ)=8θ−2tanθ b. If a and b are positive numbers, find the maximum value of f ( x ) = x^a(4−x)^b on the interval 0 ≤ x ≤ 4

1.Solve 3cos(2α)=3cos2(α)−23cos(2α)=3cos2(α)-2 for all solutions on the interval 0≤α<2π0≤α<2π αα =     Give your answers accurate to...

1.Solve 3cos(2α)=3cos2(α)−23cos(2α)=3cos2(α)-2 for all solutions on the interval 0≤α<2π0≤α<2π αα =     Give your answers accurate to at least 3 decimal places, as a list separated by commas 2.Solve 7sin(2w)−5cos(w)=07sin(2w)-5cos(w)=0 for all solutions on the interval 0≤w<2π0≤w<2π ww =     Give your exact solutions if appropriate, or solutions accurate to at least 3 decimal places, as a list separated by commas 3.Solve 7sin(2β)−2cos(β)=07sin(2β)-2cos(β)=0 for all solutions 0≤β<2π0≤β<2π ββ =     Give exact answers or answers accurate to 3 decimal places, as appropriate 4.Solve...

Solve the initial value problem: 4y′′+3y=0, y(π/2)=2 , y'(π/2)=−1. Give your answer as y=... Use x...

Solve the initial value problem: 4y′′+3y=0, y(π/2)=2 , y'(π/2)=−1. Give your answer as y=... Use x as the independent variable.

Solve the initial value problem: 9y″+18y′+19y=0, y(π/2)=−2, y′(π/2)=−2. Give your answer as y=... . Use x...

Solve the initial value problem: 9y″+18y′+19y=0, y(π/2)=−2, y′(π/2)=−2. Give your answer as y=... . Use x as the independent variable.

Solve the initial value problem: 9y′′−18y′+15y=09y″−18y′+15y=0, y(π/3)=2y(π/3)=2, y′(π/3)=1.y′(π/3)=1.Give your answer as y=... y=... . Use xx...

Solve the initial value problem: 9y′′−18y′+15y=09y″−18y′+15y=0, y(π/3)=2y(π/3)=2, y′(π/3)=1.y′(π/3)=1.Give your answer as y=... y=... . Use xx as the independent variable.

Solve the given equation. (Enter your answers as a comma-separated list. Let k be any integer....

Solve the given equation. (Enter your answers as a comma-separated list. Let k be any integer. Round terms to three decimal places where appropriate. If there is no solution, enter NO SOLUTION.) 2 sin(2θ) − 3 sin(θ) = 0 #### I need the answer in the format 2pik + 5pi/6, 2pik+3pi/2....etc

3.Solve the given equation. (Enter your answers as a comma-separated list. Let k be any integer....

3.Solve the given equation. (Enter your answers as a comma-separated list. Let k be any integer. Round terms to three decimal places where appropriate. If there is no solution, enter NO SOLUTION.) 2 sin2(θ) − cos(θ) = 1 #### I need the answer in the format 2pik + 5pi/6, 2pik+3pi/2....etc

Solve the equation. (2x^3+xy)dx+(x^3y^3-x^2)dy=0 give answer in form F(x,y)=c

Solve the equation. (2x^3+xy)dx+(x^3y^3-x^2)dy=0 give answer in form F(x,y)=c

Solve the following initial/boundary value problem: ∂u(t,x)/∂t = ∂^2u(t,x)/∂x^2 for t>0, 0<x<π, u(t,0)=u(t,π)=0 for t>0, u(0,x)=sin^2x...

Solve the following initial/boundary value problem: ∂u(t,x)/∂t = ∂^2u(t,x)/∂x^2 for t>0, 0<x<π, u(t,0)=u(t,π)=0 for t>0, u(0,x)=sin^2x for 0≤x≤ π. if you like, you can use/cite the solution of Fourier sine series of sin^2(x) on [0,pi] = 1/4-(1/4)cos(2x) please show all steps and work clearly so I can follow your logic and learn to solve similar ones myself.

1) Solve the given differential equation by finding, as in Example 4 of Section 2.4, an...

1) Solve the given differential equation by finding, as in Example 4 of Section 2.4, an appropriate integrating factor. (14 − 20y + e−5x) dx − 4 dy = 0 2) Solve the given initial-value problem. x dy/ dx + y = 2x + 1,   y(1) = 9 y(x) = Give the largest interval I over which the solution is defined. (Enter your answer using interval notation.) I = please show steps