For the second-order RLC circuit shown below, you can show that the inductor current satisfies the differential equation + - (R?C + 4) did(0)+(2,1) it (t) = R?LC fort 0 s. If R? = 2, R? = 2N, C = 1 mF, and L = 2 mH, then the damping ratio (C) for the inductor current response is closest to V? t=0 s L R? 1.5 O solutionspile.com

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For the second-order RLC circuit shown below, you can show that the inductor current satisfies the differential equation + - (R?C + 4) did(0)+(2,1) it (t) = R?LC fort > 0 s. If R? = 2, R? = 2N, C = 1 mF, and L = 2 mH, then the damping ratio (C) for the inductor current response is closest to V? t=0 s L R? 1.5 O  solutionspile.com

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