Using Maclaurin Series, the General Series Solution, with the First $y ^ { \prime \prime } + x ^ { 2 } y ^ { \prime } + x y = 0$

Using Maclaurin series, the general series solution, with the first three nonzero terms, of the differential equation $y ^ { \prime \prime } + x ^ { 2 } y ^ { \prime } + x y = 0$ is

A) $y = A \left( 1 + \frac { x ^ { 3 } } { 6 } + \frac { x ^ { 6 } } { 45 } - \cdots \right) + B \left( x + \frac { x ^ { 4 } } { 6 } + \frac { 5 x ^ { 7 } } { 252 } + \cdots \right)$
B) $y = A \left( 1 - \frac { x ^ { 3 } } { 6 } + \frac { x ^ { 6 } } { 45 } - \cdots \right) + B \left( x - \frac { x ^ { 4 } } { 6 } + \frac { 5 x ^ { 7 } } { 252 } - \cdots \right)$
C) $y = A \left( 1 - \frac { x ^ { 3 } } { 6 } + \frac { x ^ { 6 } } { 45 } - \cdots \right) + B \left( x + \frac { x ^ { 4 } } { 6 } + \frac { 5 x ^ { 7 } } { 252 } + \cdots \right)$
D) $y = A \left( 1 - \frac { x ^ { 3 } } { 6 } + \frac { x ^ { 6 } } { 45 } - \cdots \right) + B \left( x - \frac { x ^ { 4 } } { 6 } + \frac { 5 x ^ { 7 } } { 252 } + \cdots \right)$
E) $y = A \left( 1 + \frac { x ^ { 3 } } { 6 } + \frac { x ^ { 6 } } { 45 } + \cdots \right) + B \left( x - \frac { x ^ { 4 } } { 6 } + \frac { 5 x ^ { 7 } } { 252 } + \cdots \right)$

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