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Recall Lecture 7 Voltage Regulator using Zener Diode

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1 Recall Lecture 7 Voltage Regulator using Zener Diode
The remainder of VPS drops across Ri 2. The load resistor sees a constant voltage regardless of the current 1. The zener diode holds the voltage constant regardless of the current

2 Rectifier

3 Rectifier Circuits A DC power supply is required to bias all electronic circuits. A diode rectifier forms the first stage of a dc power supply. Diagram of an Electronic Power Supply Rectification is the process of converting an alternating (ac) voltage into one that is limited to one polarity. Rectification is classified as half-wave or full-wave rectifier.

4 Rectifier Parameters 𝑣 𝑃 𝑣 𝑆 = 𝑁 1 𝑁 2
Relationship between the number of turns of a step-down transformer and the input/output voltages - transformer ratio 𝑣 𝑃 𝑣 𝑆 = 𝑁 1 𝑁 2 The peak inverse voltage (PIV) of the diode is the peak value of the voltage that a diode can withstand when it is reversed biased Duty Cycle: The fraction of the wave cycle over which the diode is conducting.

5 Half Wave Rectifier

6 vs< V, diode off, open circuit, no current flow, Vo = 0V
vs > V, diode conducts, current flows, vo = vs – V V Equation of VO and current when diode is conducting 𝑣 𝑂 = 𝑖 𝐷 𝑅= 𝑣 𝑆 βˆ’ 𝑉 𝛾 𝑖 𝐷 = 𝑣 𝑆 βˆ’ 𝑉 𝛾 𝑅

7 Consider a sine wave where vs = vm sin t and vm is the peak value
vs < V, diode off, open circuit, no current flow, vo = 0V vs > V, diode conducts, current flows and vo = vs – V Consider a sine wave where vs = vm sin t and vm is the peak value vm Notice that the peak voltage of Vo is lower V vs > V

8 Example Consider the rectifier circuit in the figure below. Let R = 1 k, and the diode has the properties of V = 0.6 V and rf = 20 . Assume vs= 10 sin t (V) Determine the peak value of the diode current Sketch vO versus time, t. Label the peak value of vO. vs

9 SOLUTION 0.6 + IDrf + IDR – 10 = 0 ID = (10 – 0.6) / 1020 = 9.22 mA vO

10 Peak Inverse Voltage is also known as Maximum Reverse Biased Voltage
The objective is to know whether the diode can withstand a certain voltage when it is reversed and to avoid damaging the diode – each diode has PIV rating.

11 Hence, for the example just now, the PIV for the diode is 10 V
We know that the diode is reversed biased during negative cycle Diode is off, open circuit vR No current flow, hence, Vo = 0 V Using KVL -vR vs peak = 0 vR = vs peak Hence, for the example just now, the PIV for the diode is 10 V

12 Duty cycle is the fraction of the wave cycle over which the diode is conducting with respect to the full wave of the cycle 0.6 = 10 sin (1 ) 1 = sin -1 (0.6/10) = 3.44ο‚° At second quadrant for sine wave: ο‚° Hence for this example: Duty cycle= ΞΈ 2 βˆ’ ΞΈ 1 2Ο€ 𝑋 100%=48%

13 Full Wave Rectifier Center-Tapped Bridge

14 Full-Wave Rectification – circuit with center-tapped transformer
Positive cycle, D2 off, D1 conducts; vo– vs + V = 0 vo = vs - V Negative cycle, D1 off, D2 conducts; vo– vs + V = 0 vo = vs - V Since a rectified output voltage occurs during both positive and negative cycles of the input signal, this circuit is called a full-wave rectifier. Also notice that the polarity of the output voltage for both cycles is the same

15 vs = vm sin t vm V -V Notice again that the peak voltage of Vo is lower since vo = vs - V vs < V, diode off, open circuit, no current flow, vo = 0V

16 Diode is off, open circuit
For center tapped, at each cycle, there will one diode off and one diode on and vo will have a value off Because diode D2 is on, there is current in R, and vo = vs - V on Diode is off, open circuit +vR - Using KVL -vR + vo + vs peak = 0 -vR + (vspeak - V) + vs peak = 0 vR = 2vspeak - V

17 A full-wave center-tapped rectifier circuit is shown in the figure below. Assume that for each diode, the cut-in voltage, V = 0.6V and the diode forward resistance, rf is 15. The load resistor, R = 95 . Determine: peak output voltage, vo across the load, R Sketch the output voltage, vo and label its peak value. Β  ( sine wave )

18 Transformer ratio 𝑉 𝑃 𝑉 𝑆 = 𝑁 1 𝑁 2
Relationship between the number of turns of a step-down transformer and the input/output voltages 𝑉 𝑃 𝑉 𝑆 = 𝑁 1 𝑁 2

19 SOLUTION peak output voltage, Vo vs (peak) = 125 / 25 = 5V
V +ID(15) + ID (95) - vs (peak) = ID = (5 – 0.6) / 110 = 0.04 A vo (peak) = 95 x 0.04 = 3.8V Β  ii. 3.8V V -V

20 Full-Wave Rectification –Bridge Rectifier
Positive cycle, D1 and D2 conducts, D3 and D4 off; V + vo + V – vs = 0 vo = vs - 2V Negative cycle, D3 and D4 conducts, D1 and D2 off V + vo + V – vs = 0 vo = vs - 2V Also notice that the polarity of the output voltage for both cycles is the same

21 Diode is off, open circuit
For bridge rectifier, at each cycle, there will two diodes off and two diodes on and vo will have a value off on off on Diode is off, open circuit Because diode D3 and D4 is on, there is current in R, and vo = vs - 2V - vR + Using KVL -vR + vo - vR + vs peak = 0 -2vR + (vspeak - 2V) + vs peak = 0 2vR = 2vspeak - 2V vR = vspeak - V - vR +

22 Duty cycle is the fraction of the wave cycle over which the diode is conducting with respect to the full wave of the cycle one wave cycle 1 2 𝐷𝑒𝑑𝑦 𝑐𝑦𝑐𝑙𝑒= πœƒ 2 βˆ’ πœƒ 1 2πœ‹ 𝑋 100%

23 1 2 𝐷𝑒𝑑𝑦 𝑐𝑦𝑐𝑙𝑒= πœƒ 2 βˆ’ πœƒ 1 2πœ‹ 𝑋 100% Multiply by 2

24 Summary of PIV (based on Model 2)
Type of Rectifier PIV Half Wave Peak value of the input secondary voltage, vs (peak) Full Wave : Center-Tapped 2vs (peak)- V Full Wave: Bridge vs (peak) - V

25 EXAMPLE – Half Wave Rectifier Battery Charger
Determine the currents and voltages of the half-wave rectifier circuit. Consider the half-wave rectifier circuit shown in Figure. Assume VB = 6V, R = 120 Ω , V = 0.6 V and vs(t) = 18.6 sin t. Determine the peak diode current, maximum reverse-bias diode voltage, the fraction of the wave cycle over which the diode is conducting. A simple half-wave battery charger circuit -VR + VB = 0 VR = 24.6 V - VR + + -

26 This node must be at least 6.6V

27 EXAMPLE – Full Wave Rectifier Battery Charger
A full-wave bridge rectifier battery charger circuit is as shown below. Assume that the diode cut in voltage Vγ = 0.7 V and forward resistance r f =10 Ω. The transformer primary is connected to the AC power supply voltage, vp = 156 sin (t) V. Determine the peak charging current of the battery and maximum reverse biased voltage of the diode. Assume that the transformer coils turn ratio, N1:N2 = 20:1 and the battery voltage VB = 3.6 V

28 Determine the peak charging current of the battery
vs = (156 / 20) = 7.8 V VΞ³ + ID (0.010) + VB + VΞ³ + ID (0.010) – = 0 ID = (7.8 – 3.6 – 1.4) / = 140 mA 𝑉 𝑃 𝑉 𝑆 = 𝑁 1 𝑁 2 KVL Maximum reverse biased voltage - vR + - vR vR + vS peak = 0 2VR = = 11.4 VR = 5.7 V - vR +

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