Diode

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Transcript Diode 

Chap. 3 Diodes
•Simplest semiconductor device
•Nonlinear
•Used in power supplies
•Voltage limiting circuits
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3.1 Ideal Diodes
Forward bias
(on)
Reverse bias
(off)
1
I-V characteristics of an ideal diode
2
Ideal diode operation
on
off
on
off
3
Ideal diode operation
diode on
diode off
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Ideal diode operation
Vin = 24 sinwt
24
12
Vout
on
off
on
off
30
Diode conducts when 24 sinwt = 12
sinwt = 12/24
wt = 30
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Exercise 3.4(a)
I
5V
+
V
-
2.5KW
I
Find I and V
Assume diode is on.
V = 0, I = 5V/ 2.5KW
I = 2mA, implies diode is on.
5V
2.5KW
Correct assumption
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Exercise 3.4(b)
I
5V
2.5KW
+
V
-
Find I and V
Assume diode is off.
VD = - 5, ID = 0
implies diode is off.
5V
2.5KW
Correct assumption
V = 5, ID = 0
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Exercise 3.4(e)
Find I and V
+3
(Start with largest voltage)
+2
Assume D1 on,
then D2 will be off, and D3 will be off
+1
I
+
V = 3V, and I = 3V/1KW = 3mA.
V
Check assumption,
VD1 = 0, on
VD2 = -1, off
VD3 = -2, off
Correct assumption (old-style OR gate)
-
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3.6 Zener diodes
•Designed to break down at a specific voltage
•Used in power supplies and voltage regulators
•When a large reverse voltage is reached, the diode conducts.
•Vz is called the breakdown, or Zener voltage.
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Typical use of Zener diode
•The Zener diode will not usually conduct, it needs Vs > 12.5V to break down
•Assume Vs fluctuates or is noisy
•If Vs exceeds 12.5V, the diode will conduct, protecting the load
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Solving ideal diode problems
(determining if the diode is on or off)
•Assume diodes are on or off.
•Perform circuit analysis, find I & V of each diode.
•Compare I & V of each diode with assumption.
•Repeat until assumption is true.
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Prob. 3.9(b)
Are the diodes on or off?
Assume both diodes are on.
10V = (10K)I1
I1 = 10V/10K = I1 = 1mA
I1
0 = (5K)I2 - 10V, I2 = 2mA
I2
Current in D2 = I2 = 2mA, on
Current in D1 = I1 - I2 = -1mA, off
Does not match assumption; start over.
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Prob. 3.9(b)
Are the diodes on or off?
I
Assume D1 off and D2 on.
10V = (10K)I + (5K)I -10V
20V = (15K)I
I = 20V/15K = 1.33mA
Current in D2 = I = 1.33mA, on
Voltage across D1
10V - 10K(1.33mA) = -3.33V, off
Matches assumption; done.
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I-V characteristics of an ideal diode
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Solving ideal diode problems
(determining if the diode is on or off)
•Assume diodes are on or off.
•Perform circuit analysis, find I & V of each diode.
•Compare I & V of each diode with assumption.
•Repeat until assumption is true.
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Prob. 3.10(b)
Is the diode on or off?
Assume diode on.
I1
I3
I2
15V = (10K)I1 + (10K)(I1- I2)
15 = (20K)I1 - (10K)I2
1
0 = (10K)(I2- I1) + (10K)(I2- I3)
0 = -(10K)I1 + (20K)I2 - (10K)I3 2
0 = (10K)( I3- I2) + (10K)I3 + 10
-10 = -(10K)I2 + (20K)I3
3
Put 3 into 2. -5 = -(10K)I1 + (15K)I2, Put 1 into this equation, solve for I2.
I2 = 0.875mA, Current through diode is negative! Diode can’t be on.
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Prob. 3.10(b)
Assume diode off.
V1
I1
15V = (10K)I1 + (10K)I1
I1 = 0.75mA
V2
I3
I2 = 0
I2
0 = (10K)I3 + (10K)I3 + 10
I3 = -0.5mA
Find V1. V1 = (10K)I1 = 7.5V
Find V2. V2 = -(10K)I3 = 5V
Voltage across diode is V2 - V1 = -2.5V, diode is off
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3.2 Real diodes
Characteristics of a real diode
breakdown
Reverse bias
Forward bias
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Reverse bias region
•A small current flows when the diode is
reversed bias, IS
•IS is called the saturation or leakage current
IS
•IS  1nA
•-VZ is the reverse voltage at which the diode
breaks down.
•VZ is the Zener voltage in a Zener diode
(controlled breakdown).
•Otherwise, VZ is the peak inverse voltage (PIV)
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Forward bias region
•For Silicon diodes, very little current
flows until V  0.5V
•At V  0.7V, the diode characteristics are
nearly vertical
•In the vicinity of V  0.7V, a wide range of
current may flow.
•The forward voltage drop of a diode is often
assumed to be V = 0.7V
•Diodes made of different materials have different voltage drops V  0.2V - 2.4V
•Almost all diodes are made of Silicon, LEDs are not and have V  1.4V - 2.4V
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3.4 Analysis of diode circuits
(Simplified diode models) p. 159-162
•Ideal diode
•Constant-voltage drop model
•Constant-voltage drop model with resistor
•All use assumptions because actual diode characteristics
are too difficult to use in circuit analysis
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Constant-voltage drop model
I-V characteristics
•A straight line is used to represent the fast-rising characteristics.
•Resistance of diode when slope is vertical is zero.
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Constant-voltage drop model
I-V characteristics and equivalent circuit
+
-
0.7V
0.7V
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Constant-voltage drop with resistor model
I-V characteristics
•A straight line with a slope is used to represent the fast-rising characteristics.
•Resistance of diode is 1/slope.
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Constant-voltage drop with resistor model
I-V characteristics and equivalent circuit
+
0.7V
-
 50W
0.7V
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Prob. 3.9(b) (using constant voltage-drop model)
Are the diodes on or off?
Assume both diodes are on.
10V = (10K)I1 + 0.7
I1 = 9.3V/10K = I1 = 0.93mA
I1
0 = -0.7 + 0.7 + (5K)I2 - 10V, I2 = 2mA
I2
Current in D2 = I2 = 2mA, on
Current in D1 = I1 - I2 = -1.07mA, off
Does not match assumption; start over.
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Prob. 3.9(b) (using constant voltage-drop model)
Are the diodes on or off?
I
Assume D1 off and D2 on.
10V = (10K)I + 0.7 + (5K)I -10V
19.3V = (15K)I
I = 19.3V/15K = 1.29mA
Current in D2 = I = 1.29mA, on
Voltage across D1
10V - 10K(1.29mA) = -2.9V, off
Matches assumption; done.
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Prob. 3.10(b) (using constant voltage-drop model)
Is the diode on or off?
Assume diode on.
15V = (10K)I1 + (10K)(I1- I2)
15 = (20K)I1 - (10K)I2
I1
1
I3
I2
0 = (10K)(I2- I1) - 0.7 + (10K)(I2- I3)
0.7 = -(10K)I1 + (20K)I2 - (10K)I3 2
0 = (10K)( I3- I2) + (10K)I3 + 10
-10 = -(10K)I2 + (20K)I3
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Put 3 into 2. -4.3 = -(10K)I1 + (15K)I2, Put 1 into this equation, solve for I2.
I2 = 0.91mA, Current through diode is negative! Diode can’t be on.
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Prob. 3.10(b) (using constant voltage-drop model)
Assume diode off.
V1
I1
15V = (10K)I1 + (10K)I1
I1 = 0.75mA
V2
I3
I2 = 0
I2
0 = (10K)I3 + (10K)I3 + 10
I3 = -0.5mA
Find V1. V1 = (10K)I1 = 7.5V
Find V2. V2 = -(10K)I3 = 5V
Voltage across diode is V2 - V1 = -2.5V, diode is off
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3.7 Rectifier circuits
Block diagram of a dc power supply
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Half-wave rectifier
•Simple
•Wastes half the input
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Full-wave rectifier
VS > 0
VS < 0
•Current goes through load in same direction for + VS.
•VO is positive for + VS.
•Requires center-tap transformer
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Full-wave rectifier
•Entire input waveform is used
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Bridge rectifier
•A type of full-wave rectifier
•Center-tap not needed
•Most popular rectifier
VS > 0 D1, D2 on; D3, D4 off
VS < 0 D3, D4 on; D1, D2 off
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Bridge rectifier
•VO is 2VD less than VS
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Filter
•Capacitor acts as a filter.
•Vi charges capacitor as Vi increases.
•As Vi decreases, capacitor supplies current to load.
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Filter
Diode off
Diode on
•When the diode is off, the capacitor discharges.
•Vo = Vpexp(-t/RC)
•Assuming t  T, and T=1/f
VP - Vr = Vpexp(-1/fRC) half-wave rectifier (t  T)
VP - Vr = Vpexp(-1/2fRC) full-wave rectifier (t  T/2)
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