Using thevenin theorem, determine the charge and discharge equivalent circuits for the Figure 4a. sketch in b and c respectively

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470 k 5 V 100 kQ (c) Discharge equivalent circuit (a) Circuit. C = 47 µF (b) Charge equivalent circuit Figure 4: Thevenin analysis b. From the Thevenin equivalent circuit, calculate the charge time constant, (refer Figure 4b) and discharge time constant (refer Figure 4c): Tcharge = Tdischarge = c. For charging (refer Figure 4b), calculate capacitor voltage at t = tcharge- Ve = d. Assume the switch has been in the charge position long enough for the capacitor to fully charge and then the switch is move to discharge position. Now, for discharging, calculate the capacitor voltage at t = tdischarge- Ve = e. Assemble the circuit of Figure 4(a). Move the switch to charge and with the stopwatch, measure the time it takes for the voltage to reach 63.2% of its maximum capacitor voltage, Vc. Tcharge (measured) %3D Vc during maximum charge = f. Allow the capacitor to fully charge, and then move the switch to discharge and with the stopwatch, measure the time that it takes for the voltage to drop to 36.8% of its maximum capacitor voltage, Vc. Tdischarge (measured) = Ve during maximum discharge =