?^2?′′ − ??′ + (? − 3)? = 0 Classify the differential equation given below. Find...

Consider a nonhomogeneous differential equation ?′′ − 3?′ + 2? = ?3? (a) Find any particular...

Consider a nonhomogeneous differential equation ?′′ − 3?′ + 2? = ?3? (a) Find any particular solution ?? by using Lagrange’s method. (b) Find the general solution. (c) Find the particular solution if ?(0) = 1 2 and ?′(0) = 0.

For each equation below, do the following: - Classify the differential equation by stating its order...

For each equation below, do the following: - Classify the differential equation by stating its order and whether it is linear or non-linear. For linear equations, also state whether they are homogeneous or non-homogeneous. - Find the general solution to the equation. Give explicit solutions only. (So all solutions should be solved for the dependent variable y.) a. y′ = xy2 + xy. b. y′ + y = cos x c. y′′′ = 2ex + 3 cos x d. dy/dx...

Find the general solution of the given differential equation. (2 + 3x)^2 y'' − 3(2 +...

Find the general solution of the given differential equation. (2 + 3x)^2 y'' − 3(2 + 3x)y' + 9y = 81x   x > − 2/3

3. Find the general solution if the given differential equation by using the variation of parameters...

3. Find the general solution if the given differential equation by using the variation of parameters method. y''' + y'= 2 tan x, − π /2 < x < π/2

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 given higher order differential equation y^(4) + 4y^(3) − 4y^(2)...

Find the general solution of the given higher order differential equation y^(4) + 4y^(3) − 4y^(2) − 16y^(1) = 0 Derivatives of Y not power

Find the general solution of the given differential equation. y'' + 12y' + 85y = 0...

Find the general solution of the given differential equation. y'' + 12y' + 85y = 0 y(t) =

1. Find the general solution to the differential equation y''+ xy' + x^2 y = 0...

1. Find the general solution to the differential equation y''+ xy' + x^2 y = 0 using power series techniques

In this problem we consider an equation in differential form ???+???=0 The equation (6?^(1/?)+4?^3?^−3)??+(6?^2?^−2+4)??=0 in differential...

In this problem we consider an equation in differential form ???+???=0 The equation (6?^(1/?)+4?^3?^−3)??+(6?^2?^−2+4)??=0 in differential form ?˜??+?˜??=0 is not exact. Indeed, we have ?˜?−?˜?/M=______ is a function of ? alone. Namely we have μ(y)= Multiplying the original equation by the integrating factor we obtain a new equation ???+???=0 ?=____ ?=_____ Which is exact since ??=______ ??=_______ are equal. This problem is exact. Therefore an implicit general solution can be written in the form  ?(?,?)=?F where ?(?,?)=__________

Find the general solution to the given differential equation. Then, use the initial condition to find...

Find the general solution to the given differential equation. Then, use the initial condition to find the corresponding particular solution. ?′−4? = 5?^4? ; ?(0) = 0