Your answer is partially correct. Try again. Determine v(t) for the circuit of figure when $v_s(t) = 32.8cos30t$ V v(t) = \boxed{74.1}cos(30t + \boxed{52.75}^\circ) V (Express your answer as $v(t) = V_mcos(\omega t + \theta)$ where $V_m > 0$ and $-180^\circ < \theta < 180^\circ$.)
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The impedance of an inductor is given by ZL = jωL, where j is the imaginary unit and ω is the angular frequency. The impedance of a resistor is given by ZR = R, and the impedance of a capacitor is given by ZC = 1/(jωC). In this circuit, we have a resistor with Show more…
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