We consider the initial value problem 2z*y" – 5zy' + 5y = 0, y(1) = 2, y'(1) = 1 By looking for solutions in the form y = z' in an Euler-Cauchy problem Ar?y" + Bry' + Cy = 0, we obtain a auxiliary equation Ar? + (B – A)r +C = 0 which is the analog of the auxiliary equation in the constant coefficient case (1) For this problem find the auxiliary equation: =0 (2) Find the roots of the auxiliary equation: (enter your results as a comma separated list) (3) Find a fundamental set of solutions y1, p: (enter your results as a comma separated list) (4) Recall that the complementary solution (i.e., the general solution) is ye = C1y1 + c2y2. Find the unique solution satisfying y(1) = 2, y' (1) = 1

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We consider the initial value problem \(2x^2y'' - 5xy' + 5y = 0\), \(y(1) = 2\), \(y'(1) = 1\). By looking for solutions in the form \(y = x^r\) in an Euler-Cauchy problem \(Ax^2y'' + Bxy' + Cy = 0\), we obtain an auxiliary equation \(Ar^2 + (B-A)r + C = 0\), which is the analog of the auxiliary equation in the constant coefficient case. 1. For this problem, find the auxiliary equation: \[ \boxed{} = 0 \] 2. Find the roots of the auxiliary equation: (enter your results as a comma-separated list) 3. Find a fundamental set of solutions \(y_1, y_2\): (enter your results as a comma-separated list) 4. Recall that the complementary solution (i.e., the general solution) is \(y_c = c_1y_1 + c_2y_2\). Find the unique solution satisfying \(y(1) = 2\), \(y'(1) = 1\). \[ y = \boxed{} \]