Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series Assume a₀ $\neq$ 0. Assuming that a₀ = 1, one solution of the given differential equation is Differentiating as needed, which of these relationships is correct? A) $ 2 y^{\prime}(x)-a_{1}^{*}-128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 $ B) $ 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 $ C) $ 2 y^{\prime}(x)+a_{1}^{*}-128 a_{2}^{*} x-\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 $ D) $ 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 $

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The Answer of Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series Assume a₀ $\neq$ 0. Assuming that a₀ = 1, one solution of the given differential equation is Differentiating as needed, which of these relationships is correct? A) $ 2 y^{\prime}(x)-a_{1}^{*}-128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 $ B) $ 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 $ C) $ 2 y^{\prime}(x)+a_{1}^{*}-128 a_{2}^{*} x-\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 $ D) $ 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 $

Consider the Second-Order Differential Equation ≠\neq= 0 Assuming That A0 = 1, One Solution of the of Frobenius

Consider the Second-Order Differential Equation $\neq$ 0
Assuming That A₀ = 1, One Solution of the of Frobenius