Variation of Parameters

For a second-order Ordinary Differential Equation,

$$y''+p(x)y'+q(x)y = g(x).$$ (1)

Assume that linearly independent solutions $y_1(x)$ and $y_2(x)$ are known. Find $v_1$ and $v_2$ such that

$${y^*}(x) = v_1(x)y_1(x)+v_2(x)y_2(x)$$ (2)

$${y^*}'(x) = (v_1'+v_2'y_2)+(v_1y_1'+v_2y_2').$$ (3)

Now, impose the additional condition that

$$v_1'y_1+v_2'y_2 = 0$$ (4)

so that

$${y^*}'(x) = (v_1y_1'+v_2y_2')$$ (5)

$${y^*}''(x) = v_1'y_1'+v_2'y_2'+v_1y_1''+v_2y_2'.$$ (6)

Plug $y^*$, ${y^*}'$, and ${y^*}''$ back into the original equation to obtain

$$v_1(y_1''+py_1'+qy_1)+v_2(y_2''+py_2'+qy_2)+v_1'y_1'+v_2'y_2' = g(x)$$ (7)

$$v_1'y_1'+v_2'y_2' = g(x).$$ (8)

Therefore,

$$v_1'y_1+v_2'y_2 = 0$$ (9)

$$v_1'y_1'+v_2'y_2' = g(x).$$ (10)

Generalizing to an $n$th degree ODE, let $y_1$, ..., $y_n$ be the solutions to the homogeneous ODE and let $v_1'(x)$, ..., $v_n'(x)$ be chosen such that

$$\cases{ y_1v_1'+y_2v_2'+\ldots +y_nv_n' = 0\cr y_1'v_1'+y_... ...{(n-1)}v_1'+y_2^{(n-1)}v_2'+\ldots+y_n^{(n-1)}v_n' = g(x).\cr}$$ (11)

Then the particular solution is

$$y^*(x) = v_1(x)y_1(x)+\ldots +v_n(x)y_n(x).$$ (12)