electronics principles & applications sixth edition chapter 7 more about small-signal amplifiers...
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ElectronicsElectronics
Principles & ApplicationsPrinciples & ApplicationsSixth EditionSixth Edition
Chapter 7More About
Small-Signal Amplifiers(student version)
©2003 Glencoe/McGraw-Hill
Charles A. Schuler
• Amplifier Coupling
• Voltage Gain
• FET Amplifier
• Negative Feedback
• Frequency Response
INTRODUCTION
Dear Student:
This presentation is arranged in segments. Each segment is preceded by a Concept Preview slide and is followed by a Concept Review slide. When you reach a Concept Review slide, you can return to the beginning of that segment by clicking on the Repeat Segment button. This will allow youto view that segment again, if you want to.
Concept Preview• Cascade amplifiers can use capacitive coupling.
• When dc gain is required, direct coupling is required.
• The Darlington configuration is an example of direct coupling.
• Transformer coupling offers the advantage of impedance matching.
• The impedance ratio is equal to the square of the turns ratio.
• Tuned transformers provide selectivity.
VCC
These two points are at different dc voltages.
Capacitive coupling is convenient in cascade ac amplifiers.
VCC
Direct coupling is required for dc gain.
VCC
The darlington is a popular dc arrangement.
VCC
P S
10:1
10 ZRATIO = TRATIO
2
= 102 = 100
ZCOLLECTOR = 100 x 10 = 1000
Transformer coupling offers the advantage of impedance matching.
VCC
Transformer coupling can beused in bandpass amplifiers
to achieve selectivity.
fR
Gain
Amplifier Coupling Quiz
Capacitive coupling is not useful for_________ amplifiers. dc
Dc frequency response requires ________ coupling. direct
Transformer coupling offers the advantage of _________ matching. impedance
Tuned transformer coupling provides frequency _____________. selectivity
A darlington amplifier is an example of _________ coupling. direct
Concept Review• Cascade amplifiers can use capacitive coupling.
• When dc gain is required, direct coupling is required.
• The Darlington configuration is an example of direct coupling.
• Transformer coupling offers the advantage of impedance matching.
• The impedance ratio is equal to the square of the turns ratio.
• Tuned transformers provide selectivity.
Repeat Segment
Concept Preview
• The input impedance of a C-E amplifier is equal to the equivalent parallel resistance of the base divider and rin of the transistor.
• rin is times the sum of the emitter resistances when the emitter resistor is not bypassed.
• Loading the output circuit changes the clipping points and decreases the voltage gain.
• The clipping points are shown by the ac load line.
• The ac load line passes through the same Q-point as the dc load line.
RB1
EB
C
RL
VCC
RB2 RE
= 12 V
2.7 k
22 k = 2.2 k
More about solving the practical circuit for its ac conditions:
= 220
Zin = ?
RB1
EB
C
RL
VCC
RB2 RE
= 12 V
2.7 k
22 k = 2.2 k
Zin is a combination of RB1, RB2, and rin of the transistor.
= 220
rin = (RE + rE)
rin = (220 + 9.03 )
rin = 34.4 k
Note: rin = rE
when RE is bypassed.
Determine rin first:
RB1
EB
C
RL
VCC
RB2 RE
= 12 V
2.7 k
22 k = 2.2 k
= 220
Zin =1
RB2
1rin
1+
RB1
1+
++Zin =
1
2.7 k1
34.4 k1
22 k1
Zin = 2.25 k
RB1, RB2, and rin act in parallelto load the input signal.
RB1
VCC
RB2 RE
= 12 V
2.7 k
22 k RL= 2.2 k
= 220
Load = 2.2 k
What happens when an amplifier is loaded?
RL and the Load act in parallel.
RP = 1.1 k
RB1
RB2 RE
VCC = 12 V
2.7 k
22 k RL= 2.2 k
= 220
Load = 2.2 k
There are two saturation currents for a loaded amplifier.
RP = 1.1 k
ISAT(DC) = VCC
RL + RE
= 4.96 mA
ISAT(AC) = VCC
RP + RE
= 9.09 mA
0 2 4 6 8 10 12 14 16 18
2468
101214
VCE in Volts
IC in mA
20 A
0 A
100 A
80 A
60 A
40 A
There are two load lines for a loaded amplifier.
DC
TEMPORARY AC
The DC load line connects VCC and ISAT(DC).
A temporary AC load line connects VCC and ISAT(AC).
0 2 4 6 8 10 12 14 16 18
2468
101214
VCE in Volts
IC in mA
20 A
0 A
100 A
80 A
60 A
40 A
5.3 V
DC
AC
TEMP. AC
The quiescent VCE is projected to the DC load line to establish the Q-point. The AC load line is drawn through
the Q-point, parallel to the temporary AC load line.
0 2 4 6 8 10 12 14 16 18
2468
101214
VCE in Volts
IC in mA
20 A
0 A
100 A
80 A
60 A
40 A
5.3 V
AC
The AC load line shows the limits for VCE and if the Q-point is properly located.
With loaded amplifiers, the Q-point is often closer to saturation.
RB1
RB2 RE
VCC = 12 V
2.7 k
22 k RL= 2.2 k
= 220
Load = 2.2 k
What about voltage gain for a loaded amplifier?
RP = 1.1 k
AV =RP
RE + rE
AV =1.1 k
220 9.03= 4.8
VCC
Zin of the 2nd stage loads the 1st stage.
When analyzing cascade amplifiers, remember:
2nd1st
Amplifier ac Conditions Quiz
Emitter bypassing _________ an amplifier’s input impedance.
decreases
Loading at the output of an amplifier________ its voltage gain. decreases
A loaded amplifier has two load lines: dc and ___________. ac
The clipping points of a loaded amplifier are set by its _______ load line. ac
In a cascade amplifier, the Zin of a stage _______ the prior stage. loads
Concept Review• The input impedance of a C-E amplifier is
equal to the equivalent parallel resistance of the base divider and rin of the transistor.
• rin is times the sum of the emitter resistances when the emitter resistor is not bypassed.
• Loading the output circuit changes the clipping points and decreases the voltage gain.
• The clipping points are shown by the ac load line.
• The ac load line passes through the same Q-point as the dc load line.
Repeat Segment
Concept Preview• A common-source JFET amplifier uses the gate
as the input and the drain as the output.
• The forward transfer admittance (Yfs) can be determined from the drain family of curves.
• Voltage gain is equal to Yfs times RL.
• Source bias produces negative feedback and decreases the voltage gain.
• The gain with feedback is determined by the feedback ratio and the open-loop gain.
• The feedback can be eliminated with a source bypass capacitor.
Drain
Source
Gate
VDD = 20 V
VGS = 1.5 V
RGCC
RL = 5 k
Inputsignal
Common-source JFET amplifier.
Fixed bias
ISAT = 20 V
5 k= 4 mA
Phase-invertedoutput
0
2
4
1
VDS in Volts
ID in mA
5 10 15 20 25
3
-2.5
-2.0
-1.5
-1.0
-0.5
0
N-channel JFET characteristic curves
VG
S in
Vol
ts
Load line
The Q-point is set by the fixed bias.
8 VP-P
1 VP-P
AV = 8
0
2
4
1
VDS in Volts
ID in mA
5 10 15 20 25
3
-2.5
-2.0
-1.5
-1.0
-0.5
0Determining forward transfer admittance:
Yfs = ID
VGS
VG
S in
Vol
ts
VDS
1.6 mA
= 1.6 mS
D
S
G
VDD = 20 V
VGS = 1.5 V
RGCC
RL = 5 k
When the forward transfer admittance is known,the voltage gain can be determined using:
AV = Yfs x RL
= 1.6 mS x 5 k
= 8
This agrees with the graphic solution.
D
S
G
VDD
VGS = ID x RS
RGCC
RL
RS
Source bias eliminates the need for a separate VGS supply.
IS = ID
This resistor also providesac negative feedback whichdecreases the voltage gain.
Vin - BVout
A(Vin - BVout)
BVout
A = open loop gain
Summingjunction
Vin VoutA
B Feedback
A negative feedback model
B = feedback ratio
Vout = A(Vin - BVout)Vout = AVin - ABVout
AVin
Vout
1 = - ABAVin
Vout
AB +1 =Vin
Vout
AB +1A
=Vin
Vout
AB +1
A=
AB +1AVin Vout
A simplified model
D
S
G
VDD
RGCC
RL
RS
= 5 k
= 800
The feedback ratio (B) for this circuitis easy to determine since the source and
drain currents are the same.
B = 800 5 k
= 0.16
AB +1AVin Vout
Use the simplified model:
A(WITH NEG. FEEDBACK) =8
(8)(0.16) + 1= 3.51
CS
DG
VDD
RGCC
RL
RS
The source bypass capacitor will eliminate the ac negative feedback
and restore the voltage gain.
JFET Amplifier Quiz
In a common-source amplifier, the input signal goes to the _______. gate
In a common-source amplifier, the inputto output phase relationship is ____. 180o
The voltage gain of a C-S amplifier is equal to Yfs x _________. load resistance
Source bias is produced by current flow through the _______ resistor. source
An unbypassed source resistor _______ the voltage gain of a C-S amp. decreases
Concept Review• A common-source JFET amplifier uses the gate
as the input and the drain as the output.• The forward transfer admittance (Yfs) can be
determined from the drain family of curves.• Voltage gain is equal to Yfs times RL.• Source bias produces negative feedback and
decreases the voltage gain.• The gain with feedback is determined by the
feedback ratio and the open-loop gain.• The feedback can be eliminated with a source
bypass capacitor.
Repeat Segment
Concept Preview
• Dc negative feedback stabilizes the Q-point.
• Ac negative feedback decreases gain.
• Ac negative feedback increases bandwidth.
• Ac negative feedback reduces distortion.
• Amplifier gain is maximum at mid-band.
• The break frequencies are where the gain drops by 3 dB.
• Amplifier bandwidth is found by subtracting the lower break frequency from the upper break frequency.
Amplifier Negative Feedback
• DC reduces sensitivity to device parameters
• DC stabilizes operating point
• DC reduces sensitivity to temperature change
• AC reduces gain
• AC increases bandwidth
• AC reduces signal distortion and noise
• AC may change input and output impedances
0.707 Amax
A
f
The frequency response curve of an ac amplifier
Bandwidth
The gain is maximum in the midband.
Amax
Midband
The bandwidth spans the -3 dB points which are called the break frequencies.
-3dB
50
10 F
10 F
1 k
100 1k
6.8 k
The emitter bypass capacitor in this amplifier hasa significant effect on both gain and bandwidth.
Gai
n in
dB
0
50
Frequency10 Hz 100 MHz
BW1
BW2
Gain and bandwidth with and without the emitter bypass
Amplifier Frequency Response
• The lower break frequency is partly determined by coupling capacitors.
• It is also influenced by emitter bypass capacitors.
• The upper break frequency is partly determined by transistor internal capacitance.
• Both break frequencies can be influenced by negative feedback.
Concept Review• Dc negative feedback stabilizes the Q-point.
• Ac negative feedback decreases gain.
• Ac negative feedback increases bandwidth.
• Ac negative feedback reduces distortion.
• Amplifier gain is maximum at mid-band.
• The break frequencies are where the gain drops by 3 dB.
• Amplifier bandwidth is found by subtracting the lower break frequency from the upper break frequency.
Repeat Segment
REVIEW
• Amplifier Coupling
• Voltage Gain
• FET Amplifier
• Negative Feedback
• Frequency Response
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