Consider the differential equation. Find the solution y(0) = 2. dy/dt = 4t/2yt^2 + 2t^2 +...

find the general solution of the differential equation dy/dt - 2y = t^2 * e^2t

find the general solution of the differential equation dy/dt - 2y = t^2 * e^2t

Consider the differential equation y′′+ 9y′= 0.( a) Let u=y′=dy/dt. Rewrite the differential equation as a...

Consider the differential equation y′′+ 9y′= 0.( a) Let u=y′=dy/dt. Rewrite the differential equation as a first-order differential equation in terms of the variables u. Solve the first-order differential equation for u (using either separation of variables or an integrating factor) and integrate u to find y. (b) Write out the auxiliary equation for the differential equation and use the methods of Section 4.2/4.3 to find the general solution. (c) Find the solution to the initial value problem y′′+ 9y′=...

Find the general solution of the equation. d^2y/dt^2-2t/(1+t^2)*dy/dt+{2/(1+t^2)}*y=1+t^2

Find the general solution of the equation. d^2y/dt^2-2t/(1+t^2)*dy/dt+{2/(1+t^2)}*y=1+t^2

Consider the autonomous differential equation dy/ dt = f(y) and suppose that y1 is a critical...

Consider the autonomous differential equation dy/ dt = f(y) and suppose that y1 is a critical point, i.e., f(y1) = 0. Show that the constant equilibrium solution y = y1 is asymptotically stable if f 0 (y1) < 0 and unstable if f 0 (y1) > 0.

Consider the linear system dY/dt=(0 2 −2 −1)Y (a) Find the general solution. (b) Find the...

Consider the linear system dY/dt=(0 2 −2 −1)Y (a) Find the general solution. (b) Find the particular solution with the initial value Y0=(−1,1).

Find dy/dt. y=cos(sqrt 4t+12)

Find dy/dt. y=cos(sqrt 4t+12)

dy/dt - 2y = 7e^(2t) a. Determine the general solution to the associated homogeneous equation. b....

dy/dt - 2y = 7e^(2t) a. Determine the general solution to the associated homogeneous equation. b. By choosing an appropriate guess, determine a particular solution to this differential equation. c. Using your answers from parts (a) and (b), write down the general solution to the original equation d. Check that your solution is correct by plugging it into the original ODE. e. Determine the specific solution corresponding to the initial condition y(0)= 3 Pls explain how you did it

Find the general solution to the given differential equation. 1+(1+ty)e^ty+(1+t^2e^ty) dy/dt=0

Find the general solution to the given differential equation. 1+(1+ty)e^ty+(1+t^2e^ty) dy/dt=0

3. Consider the differential equation: x dy/dx = y^2 − y (a) Find all solutions to...

3. Consider the differential equation: x dy/dx = y^2 − y (a) Find all solutions to the differential equation. (b) Find the solution that contains the point (−1,1) (c) Find the solution that contains the point (−2,0) (d) Find the solution that contains the point (1/2,1/2) (e) Find the solution that contains the point (2,1/4)

Differential Equations Solve for the IVP ( y2 - 2 sin (2t) )dt + ( 1...

Differential Equations Solve for the IVP ( y2 - 2 sin (2t) )dt + ( 1 + 2ty)dy = 0 y (0)= 1