Linear Second Order ODE/x^2 y'' + 3 x y' + 10 y = 0

Theorem
The second order ODE:
 * $(1): \quad x^2 y'' + 3 x y' + 10 y = 0$

has the general solution:
 * $y = \dfrac 1 x \paren {C_1 \, \map \cos {\ln x^3} + C_2 \, \map \sin {\ln x^3} }$

Proof
$(1)$ is an instance of the Cauchy-Euler Equation:
 * $x^2 y'' + p x y' + q y = 0$

where:
 * $p = 3$
 * $q = 10$

By Conversion of Cauchy-Euler Equation to Constant Coefficient Linear ODE, this can be expressed as:
 * $\dfrac {\d^2 y} {\d t^2} + \paren {p - 1} \dfrac {\d y} {\d t^2} + q y = 0$

by making the substitution:
 * $x = e^t$

Hence $(1)$ can be expressed as:
 * $(2): \quad \dfrac {\d^2 y} {\d t^2} + 2 \dfrac {\d y} {\d t^2} + 10 y = 0$

It can be seen that $(2)$ is a constant coefficient homogeneous linear second order ODE.

From Second Order ODE: $y'' + 2 y' + 10 y = 0$, this has the general solution: