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Component values of R = 2 Ω, C = 0.800 mF, and L = 2 mH are used to construct the circuit given. If vC(0−) = 1 V and no current initially flows through the inductor, calculate i(t) at t = 1 ms, 2 ms, and 3 ms. (Round the final answers to three decimal places. ) The value of (t) at t = 1 ms is A. The value of (t) at t = 2 ms is A. The value of (1) at t = 3 ms is A.

Component values of R = 2 Ω, C = 0.800 mF, and L = 2 mH are used to construct the circuit given. If vC(0−) = 1 V and no current initially flows through the inductor, calculate i(t) at t = 1 ms, 2 ms, and 3 ms. (Round the final answers to three decimal places. ) The value of (t) at t = 1 ms is A. The value of (t) at t = 2 ms is A. The value of (1) at t = 3 ms is A.

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Component values of R = 2 Ω , C = 0.800 m F , and L = 2 m H are used to construct the circuit given. If v C ( 0 ) = 1 V and no current initially flows through the inductor, calculate i ( t ) at t = 1 m s , 2 m s , and 3 ms. (Round the final answers to three decimal places.)
The value of ( t ) at t = 1 m s is A.
The value of ( t ) at t = 2 m s is A.
The value of ( 1 ) at t = 3 m s is A .

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