Consider ODE y''' - 4y" + 13y' = 2te^(2t) sin3t 1.) Solve corresponding homogeneous ODE 2.)...

Consider the non-homogeneous equation y(4)−4y(3)+5y′′−4y′+4=2e2t+sinty(4)−4y(3)+5y″−4y′+4=2e2t+sin⁡t. The general solution of the corresponding homogeneous equation is yh=c1e2t+c2te2t+c3cost+c4sintyh=c1e2t+c2te2t+c3cos⁡t+c4sin⁡t. What...

Consider the non-homogeneous equation y(4)−4y(3)+5y′′−4y′+4=2e2t+sinty(4)−4y(3)+5y″−4y′+4=2e2t+sin⁡t. The general solution of the corresponding homogeneous equation is yh=c1e2t+c2te2t+c3cost+c4sintyh=c1e2t+c2te2t+c3cos⁡t+c4sin⁡t. What is the form of a particular solution ypyp?

Variation of Parameters. ODE y''+4y=cot^2(2t)

Variation of Parameters. ODE y''+4y=cot^2(2t)

Non homogeneous eq w constant; undetermined coefficients Find the general solution: 1) y" + 4y' +...

Non homogeneous eq w constant; undetermined coefficients Find the general solution: 1) y" + 4y' + 4y = xe^−x. 2) y" + 2y' + 5y = e^2x cos x. Determine a suitable form for a particular solution z = z(x) of the given equations 1) y" + 2y' = 2x + x^2e^−3x + sin 2x. 2) y" − 5y' + 6y = 2e^2x cos x − 3xe^3x + 5. 3) y" + 5y' + 6y = 2e^2x cos x −...

The homogeneous solutions to an ODE are sin(2t) and cos(2t). Suppose that the forcing function is...

The homogeneous solutions to an ODE are sin(2t) and cos(2t). Suppose that the forcing function is 1.5 cos(2t) what is an appropriate form of the general solution? y(t)=Acos2t +Bsin2t + C t cos(2t+ᶲ) ,        (b) y(t)=Acos2t +Bsin2t + C cos2t + Dsin2t y(t)=Acos2t +Bsin2t,                                      (d) y(t)=Acos2t +Bsin2t + C cos(2t+ᶲ) What is the total number of linearly independent solutions that the following ODE must have? y" +5y'+6xy=sinx Two       (b) Four                (c) Three              (d) Five

2)(20 pts.) Find the general solution of the non-homogeneous differential equation y^(4) −4y^(3) +15y′′ −22y′ +10y...

2)(20 pts.) Find the general solution of the non-homogeneous differential equation y^(4) −4y^(3) +15y′′ −22y′ +10y = 2cos2x+e^x. Determine the complementary solution yc and particular solution yp do not evaluate the coefficients of yp. (I find it harder to evaluate without coefficients can you please especially pay attention to that, I promise I will give thumbs up)

Solve the IVP with Cauchy-Euler ODE: x^2 y''+3xy'+4y=0; y(1)=0, y’(1)=−2

Solve the IVP with Cauchy-Euler ODE: x^2 y''+3xy'+4y=0; y(1)=0, y’(1)=−2

1. Consider the following equation that occurs in the study of the fluid flows: dy/dt=4y-y^2 (1)...

1. Consider the following equation that occurs in the study of the fluid flows: dy/dt=4y-y^2 (1) Leibniz came up with a clever substitution that converts the above non-linear ordinary differ-ential equation (ODE) into a linear ODE. (a) Use the change of variables (u=y−1), to obtain a linear ODE for the dependent variable u; i.e. obtain an equation with u as dependent variable and t and independent variable,completely eliminating y. (b) Solve the linear ODE for u and then substitute for...

solve non-homogeneous de y" - y' - 2y = 6x + 5 -2e^x by finding- the...

solve non-homogeneous de y" - y' - 2y = 6x + 5 -2e^x by finding- the solution yh(x) to the equivalent homogeneous de the particular solution yp(x) using undetermined coefficients the general solution y(x) = yh(x) + yp(x) of the de

Use Laplace Transforms to solve the given initial value problem y''-4y'+4y=t^3e6(2t) y(0)=1 and y'(0)=-2

Use Laplace Transforms to solve the given initial value problem y''-4y'+4y=t^3e6(2t) y(0)=1 and y'(0)=-2

Having some trouble finding c1 and c2, Solve the IVP y'' - 4y' + 13y =...

Having some trouble finding c1 and c2, Solve the IVP y'' - 4y' + 13y = 0, y(pi) = 3, y(pi) = 2 Thank you!!