Chapter 10 Diodes

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Chapter 10Diodes
Basic Diode Concepts Load-Line Analysis of Diode
Circuits Zener-Diode Voltage-Regulator
Circuits Ideal-Diode Model Piecewise-Linear Diode
Models Rectifier Circuits Wave-Shaping
Circuits Linear Small-Signal Equivalent Circuits
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Chapter 10Diodes
1. Understand diode operation and select diodes
for various applications. 2. Analyze nonlinear
circuits using the graphical load-line technique.
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3. Analyze and design simple voltage-regulator
circuits. 4. Solve circuits using the
ideal-diode model and piecewise-linear
models. 5. Understand various rectifier and
wave-shaping circuits. 6. Understand
small-signal equivalent circuits.
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Shockley Equation
k 1.38 1023 J/K is Boltzmanns constant and
q 1.60 1019 C is the magnitude of the
electrical charge of an electron. At a
temperature of 300 K, we have
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Zener Diodes
Diodes that are intended to operate in the
breakdown region are called Zener diodes.
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LOAD-LINE ANALYSIS OF DIODE CIRCUITS
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ZENER-DIODE VOLTAGE-REGULATOR CIRCUITS
A voltage regulator circuit provides a nearly
constant voltage to a load from a variable source.
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Load-Line Analysis of Complex Circuits
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IDEAL-DIODE MODEL
The ideal diode acts as a short circuit for
forward currents and as an open circuit
with reverse voltage applied.
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Assumed States for Analysis of Ideal-Diode
Circuits
1. Assume a state for each diode, either on
(i.e., a short circuit) or off (i.e., an open
circuit). For n diodes there are 2n possible
combinations of diode states. 2. Analyze the
circuit to determine the current through the
diodes assumed to be on and the voltage across
the diodes assumed to be off.
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3. Check to see if the result is consistent with
the assumed state for each diode. Current must
flow in the forward direction for diodes assumed
to be on. Furthermore, the voltage across the
diodes assumed to be off must be positive at the
cathode (i.e., reverse bias). 4. If the results
are consistent with the assumed states, the
analysis is finished. Otherwise, return to step 1
and choose a different combination of diode
states.
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PIECEWISE-LINEAR DIODE MODELS
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Peak Inverse Voltage
An important aspect of rectifier circuits is the
peak inverse voltage (PIV) across the diodes.
The capacitance required for a full-wave
rectifier is given by
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LINEAR SMALL-SIGNAL EQUIVALENT CIRCUITS
The small-signal equivalent circuit for a diode
is a resistance.
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Notation for Currents and Voltages in Electronic
Circuits

• vD and iD represent the total instantaneous
  diode voltage and current. At times, we may wish
  to emphasize the time-varying nature of these
  quantities, and then we use vD(t) and iD(t)
• VDQ and IDQ represent the dc diode current and
  voltage at the quiescent point.

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• vd and id represent the (small) ac signals. If
  we wish to emphasize their time varying nature,
  we use vd(t) and id(t).

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