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Diode Circuits: Applications. Applications – Rectifier Circuits Half-Wave Rectifier Circuits.

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Presentation on theme: "Diode Circuits: Applications. Applications – Rectifier Circuits Half-Wave Rectifier Circuits."— Presentation transcript:

1 Diode Circuits: Applications

2 Applications – Rectifier Circuits Half-Wave Rectifier Circuits

3 Applications – Rectifier Circuits Battery-Charging Circuit

4 Half-Wave Rectifier with Smoothing Capacitor Large Capacitance i=dq/dt or Q = I L T Q = V r C then C ~ (I L T) / V r

5 Half-Wave Rectifier with Smoothing Capacitor Large Capacitance Forward bias charge cycle Reverse bias discharge cycle Start V r Peak-to-peak riple voltage i=dq/dt or Q = I L T Q = V r C then C ~ (I L T) / V r typically :V L ~V m - (V r /2)

6 Full-Wave rectifier Circuits The sources are out of phase

7 Wave Shaping Circuits Clipper Circuits Batteries replaced by Zener diodes Review examples: 10.14 10.15 10.16 10.17 10.18

8 600 mV + 600 mV I 600 mV I flow below 600 mV I 600 mV I flow Above 600 mV 600 mV - 600 mV Half-Wave Limiter Circuits Current flows thru the resistor until +600 mV is reached, then flows thru the Diode. The plateau is representative of the voltage drop of the diode while it is conducting. Voltage divider

9 Linear Small Signal Equivalent Circuits (1) When considering electronic circuits in which dc supply voltages are used to bias a nonlinear devices at their operating points and a small ac signal is injected into the circuit to find circuit response: Split the analysis of the circuit into two parts: (a)analyze the dc circuit to find the operating point (b)consider the small ac signal

10 Linear Small Signal Equivalent Circuits (1) Since virtually any nonlinear ch-tic is approximately linear (straight) if we consider a sufficiently small segment THEN We can find a linear small-signal equivalent circuit for the nonlinear device to use in the ac analysis The small signal diode circuit can be substituted by a single equivalent resistor.

11 Linear Small Signal Equivalent Circuits (2) dc supply voltage results in operation at Q An ac signal is injected into the circuit and swings the instantaneous point of operation slightly above and below the Q point For small changes  i D –the small change in diode current from the Q-point  v D –the small change in diode voltage from the Q-point (di D /dv D ) – the slope of the diode ch-tic evaluated at the point Q

12 Linear Small Signal Equivalent Circuits (2) dc supply voltage results in operation at Q An ac signal is injected into the circuit and swings the instantaneous point of operation slightly above and below the Q point For small changes  i D –the small change in diode current from the Q-point  v D –the small change in diode voltage from the Q-point (di D /dv D ) – the slope of the diode ch-tic evaluated at the point Q Dynamic resistance of the diode

13 From small signal diode analysis Differentiating the Shockley eq. … and following the math on p.452 we can write that dynamic resistance of the diode is Linear Small Signal Equivalent Circuits (3) where

14 Example - Voltage-Controlled Attenuator DC control signal C 1, C 2 – small or large ? C in dc circuit – open circuit C in ac circuit –short circuit Find the operating point and perform the small signal analysis to obtain the small signal voltage gain

15 Example - Voltage-Controlled Attenuator DC control signal Dc circuit for Q point (I DQ, V DQ ) Compute at the Q point (I DQ, V DQ )

16 Example - Voltage-Controlled Attenuator The dc voltage source is equivalent to a short circuit for ac signals. Voltage gain

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