Emitter Transistor Amplifier Vjezba
4
Common Emitter Transistor A mp lif ier CIRCUIT TRCE.CIR Download the SPICE file Here’s a classic circuit that’s still an essential building block of circuits today, both IC and discrete. VOLTAGE GAIN Suppose you’re asked to design a transistor amplifier for a voltage gain of 3. The gain from the base to the collector can be approximated by the collector resistance over the emitter resistance. where RC’ is the AC resistance seen by the collector, RC|| RL, and RE’ is the AC resistance seen by the emitter, RE1. Why include RE2 in the c ircuit if its AC bypassed by CE? The emitter resistance performs 2 functi ons: RE1 influences the AC volt age gain and RE1+RE2 controls the DC bias. (More on bias below.) With minimal loading (RL=100K), the voltage gain is Vc / Vb = -RC / RE1 = -1800 / 600 = -3. Run a simulation and view the transient response at the base V(3) and collector V(4). Did the circuit achieve its expected gain?
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Transcript of Emitter Transistor Amplifier Vjezba
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Common Emit ter Transis tor Amp l i fier
CIRCUIT
TRCE.CIR Download the SPICE file
Here’s a classic circuit that’s still an essential building block of circuits today, both IC
and discrete.
VOLTAGE GAIN
Suppose you’re asked to design a transistor amplifier for a voltage gain of 3. The gain
from the base to the collector can be approximated by the collector resistance over the
emitter resistance.
where RC’ is the AC resistance seen by the collector, RC|| RL, and RE’ is the AC
resistance seen by the emitter, RE1. Why include RE2 in the circuit if its AC bypassed by CE? The emitter resistance performs 2 functions: RE1 influences the AC voltage
gain and RE1+RE2 controls the DC bias. (More on bias below.)
With minimal loading (RL=100K), the voltage gain is Vc / Vb = -RC / RE1 = -1800 /
600 = -3. Run a simulation and view the transient response at the base V(3) and
collector V(4). Did the circuit achieve its expected gain?
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HANDS-ON DESIGN You can Increase the gain by choosing a smaller RE1 such as
300 ohms. The gain should increase to -1800 / 300 = -6.But don’t run a simulation yet!
Maintain the same bias condition by increasing RE2 to 900 ohms so that RE1 + RE2 =
1200 ohms. Run a new simulation. Did the circuit achieve its expected gain?
OUTPUT SWING LIMITS
CIRCUIT ANALYSIS How far can you drive the output voltage before it significantly
distorts? Increase the sinewave amplitude from 0.2 to 0.5 V peak, for example, by
editing the VS statement to look like
VS 1 0 AC 1 sin(0 0.5 10kHz)
Rerun a simulation and check the output swing at V(4). Keep increasing the sine wave
amplitude till the output distorts. What is the output swing capability of the amplifier?
FREQUENCY RESPONSE
Over what frequency range can you use this amplifier? The “AC 1” in the VS
statement generates a voltage source of 1VRMS for the AC (frequency) sweepanalysis. To check the response of the entire amplifier, sun a simulation and plot the
AC results at V(7).
CIRCUIT ANALYSIS What are the lower, fL ,and upper, fU, cutoff frequencies of the
amplifier? These are the points where the gain falls to 0.707 of the midband gain. For
example, if your midband gain is 6, your cutoff frequencies occur where the gain
decreases to 6 x 0.707 = 4.24 V/V. The bandwidth of your circuit is simply fBW = fU
– fL.
HANDS-ON DESIGN Suppose your application must pass 10 kHz but ignore 60 Hz
interference. Does the bandwidth of this amplifier include 60Hz? You can change the
lower cutoff frequency fL by adjusting C1. C1 forms a time constant with RS and the
input impedance of the amplifier. What value of C1 is needed to reduce the 60 Hz
response to about 1/10 of the midband gain while still passing the 10 kHz frequency?
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BIAS POINT
SPICE calculates the small signal bias point (initial voltages) and places the result in
the output (*.out) file. View this file by selecting View > Output File from theWindows menus. The voltages are listed in a table by node and voltage.
CIRCUIT ANALYSIS Two parameters determine the collector current of the CE
amplifier: the emitter voltage (node 5) and total emitter resistance, Ic = V(5) / (RE1 +
RE2). What is the initial voltage at V(5) and initial collector current?
SIMULATION NOTE
Note that the transistor Q1 requires more parameters than a resistor or capacitor. The
Q1 statement “Q1 4 3 5 Q2N2222” includes a model name Q2N2222. The model
name refers to the model statement which specifies the parameters that describe the
transistor's behavior. The device parameters are typically generated by the
manufacturer and made available on their web site.
You may see an NPN model that does not specify all of the parameters. The unlisted
parameters will be assigned their default values. For example, a transistor with all
default parameters except current gain BF=150 is described as
.model QXXXX NPN(BF=150)
SPICE FILE
Download the file or copy this netlist into a text file with the *.cir extention.
TRCE.CIR - TRANSISTOR COMMON EMMITER
*
VS 1 0 AC 1 SIN(0 0.2 10KHZ)
VCC 10 0 DC 12
*
RS 1 2 100
C1 2 3 1UF
R1 10 3 22K
R2 3 0 11K
Q1 4 3 5 Q2N2222
RC 10 4 1800
RE1 5 6 600
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RE2 6 0 600
CE 6 0 50UF
CL 4 7 10UF
RL 7 0 100K
*
.model Q2N2222 NPN(Is=3.108f Xti=3 Eg=1.11 Vaf=131.5 Bf=217.5 Ne=1.541
+ Ise=190.7f Ikf=1.296 Xtb=1.5 Br=6.18 Nc=2 Isc=0 Ikr=0 Rc=1
+ Cjc=14.57p Vjc=.75 Mjc=.3333 Fc=.5 Cje=26.08p Vje=.75
+ Mje=.3333 Tr=51.35n Tf=451p Itf=.1 Vtf=10 Xtf=2 Rb=10)
*
* ANALYSIS
.AC DEC 5 10 10MEG
.TRAN 0.001MS 0.2MS
* VIEW RESULTS
.PLOT AC V(2) V(5)
.PLOT TRAN V(2) V(5)
.PROBE
.END
