Respuesta :
Answer:
Step-by-step explanation:
We will use the reduction of order to solve this equation. At first, we need a solution of the homogeneus solution.
Consider the equation [tex]y''+2y'+y=0[/tex] We will assume that the solution is of the form [tex]y=Ae^{rx}[/tex]. If we plug this in the equation, we get
[tex]Ae^{rx}(r^2+2r+1)=0[/tex]
Since the exponential function is a positive function, and A should be different to zero to have non trivial solutions, we get
[tex]r^2+2r+1=0[/tex]
By using the quadratic formula, we get the solutions
[tex]r= \frac{-2\pm \sqrt[]{4-4}}{2}=-1[/tex]
So one solution of the homogeneus equation is of the form [tex]y=Ae^{-x}[/tex]. To use the reduction of order assume that
[tex] y = v(x)y_h[/tex]
where [tex]y_h = Ae^{-x}[/tex]. We calculate the derivatives and plug it in the equation
[tex] y' = v'y_h+y_h'v[/tex]
[tex]y'' = v''y_h+v'y_h'+y_h'v'+y_h''v = v''y_h+2v'y_h+y_h''v[/tex]
[tex](v''y_h+2v'y_h'+y_h''v)+2(v'y_h+y_h'v)+vy_h = 0[/tex]
If we rearrange the equation we get
[tex]v''y_h+(2y_h'+2y_h)v'+v(y_h''+2y_h'+y_h)=0[/tex]
Since [tex]y_h[/tex] is a solution of the homogeneus equation we get
[tex]v''y_h+(2y_h'+2y_h)v'=0[/tex]
If we take w = v', then w' = v''. So, in this case the equation becomes
[tex]w'y_h+(2y_h'+2y_h)w=0[/tex]
Note that [tex]y_h' = -1y_h[/tex] so
[tex]w'y_h=0[/tex]. Since [tex]y_h[/tex] cannot be zero, this implies
w' =0. Then, w = K (a constant). Then v' = K. So v=Kx+D where D is a constant.
So, we get that the general solution is
[tex] y = vAe^{-x} = (Kx+D)Ae^{-x} = Cxe^{-x} + Fe^{-x}[/tex] where C, F are constants.
