Consider the full-wave rectifier circuit below. Use a constant voltage drop model for the diodes with...
For the fullwave rectifier circuit shown below, the input voltage is Vi 6 sin 2n60t and the diodes D1, D2, D3, D4 each have a forward- voltage drop of 0.7 V when conducting. Determine the average value of the output voltage Vo (in V). (Enter your answer as a number without the units.)
QUESTION 14 If practical diodes are used in the bridge rectifier circuit thown below, the peak inverse voltage, PIV for the diode D1 will be equal to2markt) Di Ds oan PumB Ri. D2 D4 Vplout)-0.7 volts Vplsec)-0.7 volts Vplot2+0.7 volts Vplout QUESTION 14 If practical diodes are used in the bridge rectifier circuit thown below, the peak inverse voltage, PIV for the diode D1 will be equal to2markt) Di Ds oan PumB Ri. D2 D4 Vplout)-0.7 volts Vplsec)-0.7 volts Vplot2+0.7...
A full-wave bridge rectifier is constructed using 4 germanium diodes, each with a forward voltage drop of 0.3 V. The rectified waveform is described by the function vout(θ) = Vs sin θ - 2 VD where θ = sin-1 (2VD/Vs). Use integration to determine the exact average value of Vout for Vs = 1.5, 2, 2.5, 3, 3.5, 4, and 4.5 V (using Excel or Matlab will speed up this process considerably). Then use the estimation formula (0.636 Vs -...
Consider the two-sided limiter circuit below. Let the load resistor RLoad = 1 kQ. The gain must be 0.8 V/V in the region where the diodes are not limiting. Use a constant voltage drop model for the diodes with VD = 0.7 V. 3. out D2 (1+2 pts) Find the value for voltage source V1 that causes D1 to start limiting the output voltage at -5 V. a. D3 D1 Vin R2 b. (1+2 pts) Find the value for voltage...
3. Consider the full-wave bridge rectifier circuit shown below. The full-wave bridge is made using silicon diodes. 120V 15V 120 V(ms) n 60 Hz 752 Vout a. Find the maximum value of VoUT, and the voltage rating for the capacitor assuming a 50% margin of safety. b. Choose the capacitance of the filter capacitor for a peak-to-peak ripple of 1V, and determine the corresponding peak diode current. What is the frequency of the ripple voltage? c. Now suppose the filter...
In the circuit below, T1 is rated 12V RMS secondary voltage, D1, D2, D3 &D4 are IN4001 rectifying diodes and RL is 1.8ΚΩ. Given that RI-2202, and R2 1.2KQ, use the formula provided to calculate the output voltage (Vo) of the LM317 voltage regulator. Provide an answer in engineering notation, correct to 3 significant figures. 1 A Vo= 1.25V (1 + R2/ R1) Da AC line C CT input 60 Hz NC D, CI 120 V/12 V R2 In the...
For the diodes, use the models shown below; the regular diode model has 0.7V forward bias voltage; the Zener diode model has -3V breakdown voltage Question 2 (25 points) For the diodes, use the models shown below; the regular diode model has 0.7V forward bias voltage; the Zener diode model has -3V breakdown voltage. a) Determine the minimum positive value of in to make D1 conduct current. (10 pts) b) Determine the minimum positive value of lin to make D2...
In the circuit below, T1 is rated 14.3V RMS secondary voltage, D1, D2, D3 & D4 are IN4001 rectifying diodes and RL is 3.3KQ. Given that R1-5600, and R2-2.2K2, use the formula provided to calculate the output voltage (Vo) of the LM317 voltage regulator. Provide an answer in engineering notation, correct to 3 significant figures. 1 A Vo= 1.25V (1+ R2/ R1) D2 Ds CT AC line nput 60 Hz LM317 NC Di Со RL 120 V/ 14.3 v R2...
Vs =10 pk VD=0.7 F=40Hz Given this ciruit the ripple voltage is calcuted using the following equations for CR>>T/2 vr with no capacitor = Vs -2*VD Vr with capacitor = Vs-2VD / 2R*F*C Load VR theory VR experiment R no capacitor 8.6 V 8.8V C=10uF 2.287 V 2.2 V C=22uF 1.039 V 1.08 V C=47uF 486.6 mV 394 mV Give possible reasons for the variation between the theoretical and experimental results. Hint: deals with ideal diode and CR>>T/2. D1 D2...
Q5: In the following circuit, identical diodes Dl and D2 use constant voltage drop (CVD) model. VD,ON = 800 mV, R1 = 1 K. Determine the change in Vout if Vin changes from +2.4V to +2.5V. (Hint: use small signal model) Vin - DR Nyu out 'out 1K12 z Q6: The following BJT circuit has VBE = 0.8V, VA = 10V, Vcc = 2.5V. The amplifier must be designed for maximum small signal voltage gain Ay, while maintaining Q1 operating...