ecd2 fet biasing - fallzabdesk.szabist.edu.pk
TRANSCRIPT
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Chapter 2
FET Biasing
CH 2
FET
Biasing
2013 ور، 08،
2
CH 2
FET
Biasing
2013 ور، 08،
Spring 2013
ME-2401
Electronic Circuit Design
4th Semester (Mechatronics)
SZABIST, Karachi
Course Support
Office: 100 Campus (404)
Ext. (120)
Official: ZABdesk
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Chapter Contents
• Fixed biased
• Self biased
• Voltage Divider Biasing
• Common Gate
• Configurations of D-MOSFETs
• Configurations of E-MOSFETs
• p-channel FET configurations
• Practical Applications
• Computer Analysis
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5
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Introduction
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Amplifier Device Analysis:
Introduction 6
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AmplifierAC signal
DC Bias
Output (Amplified)
• DC analysis: DC Bias analysis (AC suppressed)
• AC analysis: AC input signal analysis (DC Suppressed)
• Hybrid analysis: AC & DC
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Common JFET Biasing Circuits:
JFET Biasing Circuits
• Fixed – Bias
• Self-Bias
• Voltage-Divider Bias
D-Type MOSFET Biasing Circuits
• Self-Bias
• Voltage-Divider Bias
E-Type MOSFET Biasing Circuits
• Feedback Configuration
• Voltage-Divider Bias
Introduction 7
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Basic Current Relationships:
• For all FETs:
• For JFETS and D-Type MOSFETs:
• For E-Type MOSFETs:
Introduction 8
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1
≅ 0
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9
JFET Configurations
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Fixed Biased
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JFET Fixed Bias:
Fixed Biased 11
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Coupling capacitors (Open
for DC & short for AC)
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Fixed Biased 12
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0
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JFET Fixed Bias:
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Plotting Shockley’s equation
Fixed Biased 13
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Finding the solution for the fixed-bias
configuration
Quiescent Point:
Measuring the quiescent values of ID and VGS
Fixed Biased 14
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Finding Quiescent Point in Lab:
Determine the following:
Fixed Biased 15
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Example 7-1:
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Fixed Biased 16
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Example 7-1:
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Fixed Biased 17
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Computer Analysis
-8 -7 -6 -5 -4 -3 -2 -1 00
0.001
0.002
0.003
0.004
0.005
0.006
0.007
0.008
0.009
0.01
X: -2
Y: 0.005625
example 7-1
VGS (V)
ID (
mA
)
Example 7-1:
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Fixed Biased 18
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Computer Analysis
% JFET DC Biasing Configurations
% Fixed bias
% Example 7-1 Boylestad
RD = 2000; VGG= 2; VDD = 16; IDSS = 10/1000; Vp = -8;
VGS = Vp:0.1:0;
ID = IDSS*(1-VGS/Vp).^2;
plot(VGS,ID), grid on,
title('example 7-1') , xlabel('VGS (V)'), ylabel('ID (mA)')
% Fixed bias line
hold,
plot(-VGG,ID,'*')
Example 7-1:
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Self Bias
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JFET: Self Biased
Self Bias 20
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DC Analysis:
Self Bias 21
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Calculations:For the indicated loop,
To solve this equation:
• Select an ID < IDSS and use the component value of RS to calculate VGS
• Plot the point identified by ID and VGS. Draw a line from the origin of the
axis to this point.
• Plot the transfer curve using IDSS and
VP (VP = VGSoff in specification sheets) and a few points such as ID = IDSS /
4 and ID = IDSS / 2 etc.
The Q-point is located where the first line intersects the transfer curve. Use the
value of ID at the Q-point (IDQ) to solve for the other voltages:
Self Bias 22
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Calculations:
Self Bias 23
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Calculations:
Self Bias 24
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Determine the following:
Self Bias 25
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Example 7-2:
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Self Bias 26
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Example 7-2:
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Self Bias 27
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Example 7-2:
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Self Bias 28
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Example 7-2:
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Self Bias 29
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Computer Analysis
-8 -7 -6 -5 -4 -3 -2 -1 00
1
2
3
4
5
6
7
8x 10
-3
X: -2.601
Y: 0.002601
Example 7-2
VGS (V)
ID (
mA
)
Example 7-2:
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Self Bias 30
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Computer Analysis
%% EXAMPLE 7-2
% Self Bias Configuration
RD = 3300; Rs=1000; IDSS = 8/1000; Vp = -6; VDD = 20;
VGS = Vp:0.001:0;
ID = IDSS*(1-VGS/Vp).^2;
plot(VGS,ID), grid on,
title('Example 7-2') , xlabel('VGS (V)'), ylabel('ID (mA)')
% self bias line calculations
Vgs = -ID*Rs;
hold,
plot(Vgs, ID,'r.-')
Example 7-2:
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Find the quiescent point for the given network: (Example 7.2)
Self Bias 31
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Example 7-3:
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Find the quiescent point for the given network: (Example 7.2)
Self Bias 32
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%% EXAMPLE 7-3
% Self Bias Configuration
RD = 3300; IDSS = 8/1000; Vp = -6; VDD = 20;
VGS = Vp:0.001:0;
ID = IDSS*(1-VGS/Vp).^2;
plot(VGS,ID), grid on,
title('Example 7-3') , xlabel('VGS (V)'), ylabel('ID (mA)')
% self bias line calculations for Rs = 100 Ohms
Rs=100;
Vgs = -ID*Rs;
hold,
plot(Vgs, ID,'r.-')
% self bias line calculations for Rs = 10k Ohms
Rs = 10000;
Vgs = -ID*Rs;
plot(Vgs, ID,'m.-')
Computer AnalysisExample 7-3:
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Find the quiescent point for the given network: (Example 7.2)
Self Bias 33
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-8 -6 -4 -2 0 20
1
2
3
4
5
6
7
x 10-3
X: -0.6401
Y: 0.006401
Example 7-3
VGS (V)
ID (
mA
)
Computer AnalysisExample 7-3:
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Voltage Divider
Bias
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VDB:
Voltage Divider Bias 35
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IG = 0 A
ID responds to changes in VGS
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VDB:
Voltage Divider Bias 36
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• The Q point is established by
plotting a line that intersects the
transfer curve.
• VG is equal to the voltage across divider resistor R2:
• Using Kirchhoff’s Law:
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VDB:
Voltage Divider Bias 37
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• IG = 0 A and ID responds to changes in VGS
• Using the value of ID at the Q-point, solve for
the other variables in the voltage-divider
bias circuit:
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;
VDB Q-point:
Voltage Divider Bias 38
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Step 1
Plot the line by plotting two points:
• VGS = VG, ID = 0 A
• VGS = 0 V, ID = VG / RS
Step 2
Plot the transfer curve by plotting
IDSS, VP and the calculated values of
ID
Step 3
The Q-point is located where the
line intersects the transfer curve
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Effect of increasing RS:
Voltage Divider Bias 39
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For the given network, find:
a. IDQ and VGSQ
b. VD and VS
c. VDS and VDG
Voltage Divider Bias 40
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Example 7-5:
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Voltage Divider Bias 41
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Example 7-5:
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Voltage Divider Bias 42
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%% EXAMPLE 7-5
% Voltage Divider Bias Configuration
R1 = 2.1*10^6; R2 = 270*10^3; RD = 2400;
IDSS = 8/1000; Vp = -4; VDD = 16;
VGS = Vp:0.1:0;
ID = IDSS*(1-VGS/Vp).^2;
plot(VGS,ID), grid on,
title('Example 7-5') , xlabel('VGS (V)')
ylabel('ID (A)')
% Load line (Voltage Divider Bias)
calculations
% Rs = 1.5k Ohms
Rs=1500;
Vg = VDD*R2/(R1+R2);
Vgs = Vg-(ID*Rs);
hold,
plot(Vgs, ID,'r.-')-12 -10 -8 -6 -4 -2 0 20
1
2
3
4
5
6
7
8x 10
-3
X: -7.594e-005
Y: 0.001215
Example 7-5
VGS (V)
ID (
A)
X: -1.801
Y: 0.002416
X: 1.823
Y: 0
X: -8
Y: 0.006549
Example 7-5:
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Practive 43
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Problem 1 & 2:
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Practive 44
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Problem 3 & 6:
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Practive 45
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Problem 12 & 14:
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Common Gate
Configuration
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Common Gate:
Common Gate Configuration 47
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Common Gate:
Common Gate Configuration 48
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I
V
V
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Determine the following: IDQ, VGSQ, VDS, VD and VS:
Common Gate Configuration 49
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Example 7-4:
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Determine the following: (RD = 1.5 kΩ, RS = 680 Ω, VDD = 12 V)
Common Gate Configuration 50
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Example 7-6:
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Common Gate Configuration 51
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-9 -8 -7 -6 -5 -4 -3 -2 -1 00
0.002
0.004
0.006
0.008
0.01
0.012Example 7-6
VGS (V)
ID (
A)
X: 0
Y: 0
X: -5.007
Y: 0.007363
X: -2.62
Y: 0.003853
%% EXAMPLE 7-6: % Common Gate
Configuration
RD = 1500; IDSS = 12/1000; Vp = -6;
VDD = 12;
VGS = Vp:0.1:0;
ID = IDSS*(1-VGS/Vp).^2;
plot(VGS,ID), grid on,
title('Example 7-6') , xlabel('VGS (V)')
ylabel('ID (A)')
% Load line (Common Gate) calculations
for
% Rs = 680 Ohms
Rs=680;
Vss = 0;
Vgs = Vss-(ID*Rs);
hold,
plot(Vgs, ID,'r.-')
Example 7-6:
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Special Case: VGSQ = 0 V:
Common Gate Configuration 52
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I
V
V
0
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53
D-MOSFET
Configurations
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Configurations:1. Voltage Divider
2. Self Bias
3. Common Gate Special Case
D-MOSFETs 54
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Voltage Divider
Bias
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Voltage Divider Bias:
Determine the following:
a. Q-point
b. VDS
D-MOSFETs 56
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Example 7-7:
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Determine the following: (Data of Ex. 7-7, RS = 150Ω )
D-MOSFETs 57
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Example 7-8:
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Self Bias
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Self Bias:
Determine the following, if RD = 6.2 k, RS = 2.4 k, IDSS = 8mA and VP = − 8V.
D-MOSFETs 59
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Example 7-9:
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Common Gate (Special case):
Determine VDS for the following network:
D-MOSFETs 60
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Example 7-10:
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61
E-MOSFET
Configurations
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Configurations:
1. Feedback Biasing Arrangement
2. Voltage Divider Biasing Arrangement
E-MOSFETs 62
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Feedback Bias
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The transfer characteristic for the e-type MOSFET is very different from
that of a simple JFET or the d-type MOSFET.
E-MOSFETs 64
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Feedback Biasing Arrangement:
E-MOSFETs 65
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IG = 0 A
VRG = 0 V
VDS = VGS
VGS = VDD – IDRD
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Feedback Biasing Q-point:
Step 1Plot the line using
• VGS = VDD, ID = 0 A• ID = VDD / RD , VGS = 0 V
Step 2Using values from the specification sheet, plot the transfer curve with
• VGSTh , ID = 0 A • VGS(on), ID(on)
Step 3The Q-point is located where the line and the transfer curve intersect
Step 4Using the value of ID at the Q-point, solve for the other variables in the bias circuit
E-MOSFETs 66
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Determine IDQ and VDSQ:
E-MOSFETs 67
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Example 7-11:
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E-MOSFETs 68
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Example 7-11:
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69
Voltage Divider
Bias
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Voltage Divider Bias:Plotting the line and the transfer curve to find the Q-point:
E-MOSFETs 70
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;
Voltage Divider Bias Q-point:Step 1
Plot the line using
• VGS = VG = (R2VDD) / (R1 + R2), ID = 0 A
• ID = VG/RS , VGS = 0 V
Step 2
Using values from the specification sheet, plot the transfer curve with
• VGSTh, ID = 0 A
• VGS(on) , ID(on)
Step 3
The point where the line and the transfer curve intersect is the Q-point.
Step 4
Using the value of ID at the Q-point, solve for the other circuit values.
E-MOSFETs 71
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Determine IDQ, VGSQ and VDS:
E-MOSFETs 72
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Example 7-12:
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Summary
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Summary 74
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Summary 75
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76
Design
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Determine RS and RD:
Design 77
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Example 7-15:
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Determine RS when RD = 1800 Ω, R1 = 91kΩ, R2 = 47 kΩ, VDD = 16 V, VGSQ = -2V.
Design 78
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Example 7-16:
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Determine VDD and RD , when VDS = ½ VDD and ID = ID(on).
Design 79
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Example 7-17:
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80
p-channel
FETs
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For p-channel FETs the same calculations and graphs are used, except that the
voltage polarities and current directions are reversed.
The graphs are mirror images of the n-channel graphs.
p-channel FETs 81
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p-channel JFET
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p-channel FETs 82
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p-channel D MOSFET (VDB)
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p-channel FETs 83
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p-channel E MOSFET (FB)
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p-channel FETs 84
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p-channel DMOSFET (VDB)
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p-channel FETs 85
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Determine IDQ, VGSQ and VDS:
Example 7-18:
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Applications
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Applications:
1. Voltage Controlled Resistor
2. JFET Voltmeter
3. Timer Network
4. Fiber Optic System
5. MOSFET Relay Driver
Applications 87
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Home Task 88FET
1. Exercise Problem 1, 2 and 4
2. Exercise Problem 7 and 11
3. Exercise Problem 13
4. Exercise Problem 15 and 17
5. Exercise Problem 19
6. Exercise Problem 21
7. Exercise Problem 25
8. Exercise Problem 31
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CH 1
References 89FET
1. Boylestad
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