Solve the Differential Equation x^2y'' -3x+5y=0 ?
1 Answer
y=sqrt(x)(Acos(1/2sqrt(19)lnx) + Bcos(1/2sqrt(19)lnx)) +3/5x
Explanation:
We have:
x^2y'' -3x+5y=0
This is a Euler-Cauchy Equation which is typically solved via a change of variable. Consider the substitution:
x = e^t => xe^(-t)=1
Then we have,
dy/dx = e^(-t)dy/dt , and,(d^2y)/(dx^2)=((d^2y)/(dt^2)-dy/dt)e^(-2t)
Substituting into the initial DE we get:
x^2((d^2y)/(dt^2)-dy/dt)e^(-2t) -3e^t+5y=0
:. (d^2y)/(dt^2)-dy/dt +5y=3e^t ..... [A]
This is now a second order linear Differentiation Equation. The standard approach is to look at the Auxiliary Equation, which is the quadratic equation with the coefficients of the derivatives, i.e.
m^2-m+5 = 0
We can solve this quadratic equation, and we get two complex solution:
m=1/2(1+-sqrt(19)i)
Thus the Homogeneous equation:
(d^2y)/(dt^2)-dy/dt +5y=0
has the solution:
y=e^(1/2t)(Acos(1/2sqrt(19)t) + Bcos(1/2sqrt(19)t))
We now seek a Particular Solution of [A], which will be of the form:
y = Ae^t
Differentiating wrt
y' = Ae^t , and, >y'' = Ae^t
Substituting into the DE [A} we get:
Ae^t-Ae^t+5Ae^t=3e^t
Equating coefficients we have:
A-A+5A=3 => A=3/5
Hence, the GS of [A] is the combination of the homogeneous solution and the particular solution, thus:
y=e^(1/2t)(Acos(1/2sqrt(19)t) + Bcos(1/2sqrt(19)t)) +3/5e^t
Now we initially used a change of variable:
x = e^t => t=lnx
So restoring this change of variable we get:
y=e^(1/2lnx)(Acos(1/2sqrt(19)lnx) + Bcos(1/2sqrt(19)lnx)) +3/5e^lnx
:. y=e^(lnsqrt(x))(Acos(1/2sqrt(19)lnx) + Bcos(1/2sqrt(19)lnx)) +3/5x
:. y=sqrt(x)(Acos(1/2sqrt(19)lnx) + Bcos(1/2sqrt(19)lnx)) +3/5x
Which is the General Solution
