Note: Assume ideal conditions of no reverse current through the diode and no leakage current in the capacitor. Note: The DC output voltage is approximately located at the midway point of the voltage ripple using VDC=Vp- Vr/2. Full-Wave Rectifier with Capacitor Filter For the circuit in Figure 13, determine VMax (peak after diode drops), Vr (ripple voltage), 7 (ripple factor), and the DC output voltage VDC. Vin_pp=22.8Vpp@60Hz (Vpeak-11.4V before the diode drops), RI=1350, C₁=100uF, VD=0.7V. To solve for V, and VDC, start with formula for Vr and VDC=VMax-Vr/2 and solve for Vr. Then substitute back in to solve for VDC. From Wall Outlet 120Vrms (340Vpp) Transformer DO NOT Connect these two wires! Sketch the output signal, Vout. Vin D₂ Probe RL VOUR Probe GND GND Figure 13: Full-Wave Rectifier with Capacitor Filter Repeat the calculations for C-200uF and C-2200uF. Repeat the calculations for RL=27002, C=100uF.

don't worry about doing the first part, just do both of the repeat the calculations for the problem. 

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Note: Assume ideal conditions of no reverse current through the diode and no leakage current in the capacitor. Note: The DC output voltage is approximately located at the midway point of the voltage ripple using VDC=Vp- Vr/2. Full-Wave Rectifier with Capacitor Filter For the circuit in Figure 13, determine VMax (peak after diode drops), Vr (ripple voltage), 7 (ripple factor), and the DC output voltage VDC. Vin_pp=22.8Vpp@60Hz (Vpeak-11.4V before the diode drops), RI=1350, C₁=100uF, VD=0.7V. To solve for V, and VDC, start with formula for Vr and VDC=VMax-Vr/2 and solve for Vr. Then substitute back in to solve for VDC. From Wall Outlet 120Vrms (340Vpp) Transformer DO NOT Connect these two wires! Sketch the output signal, Vout. Vin D₂ Probe RL VOUR Probe GND GND Figure 13: Full-Wave Rectifier with Capacitor Filter

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Repeat the calculations for C-200uF and C-2200uF. Repeat the calculations for RL=27002, C=100uF.