UNIT I
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Transcript of UNIT I
ELECTRONIC CIRCUITS- I
DC Biasing Circuits
RC
RB
+VCC
ic
vceib
v in
v out
• The ac operation of an amplifier depends on the initial dc values of IB, IC, and VCE.
• By varying IB around an initial
dc value, IC and VCE are made
to vary around their initial dc values.
• DC biasing is a static operation since it deals with setting a fixed (steady) level of current (through the device) with a desired fixed voltage drop across the device.
Purpose of the DC biasing circuit
• To turn the device “ON” • To place it in operation in the region of its
characteristic where the device operates most linearly, i.e. to set up the initial dc values of IB, IC, and VCE
Voltage-Divider Bias• The voltage – divider (or
potentiometer) bias circuit is by far the most commonly used.
• RB1, RB2
voltage-divider to set the value of VB , IB , C3
to short circuit ac signals to ground, while not effect the DC operating (or biasing) of a circuit
(RE stabilizes the ac signals)
Bypass Capacitor
RC
R1
+VCC
RE
R2
v out
v in
C2C1
C3
Graphical DC Bias Analysis
RC
R1
+VCC
IC
IE
RE
R2
cmxy
RR
VV
RRI
II
RIVRIV
EC
CC
CE
EC
C
EECECCCC
EC
:equation linestraight of form slope-Point
1
for
0
IC(mA)
VCE
VCE(off) = VCC
IC(sat) = VCC/(RC+RE)
DC Load Line
DC Load Line
IC(mA)
VCE
VCE(off) = VCC
IC(sat) = VCC/(RC+RE)
DC Load Line
The straight line is know as the DC load line
Its significance is that regardless of the behavior of the transistor, the collector current IC and the
collector-emitter voltage VCE must always lie on the
load line, depends ONLY on the VCC, RC and RE
(i.e. The dc load line is a graph that represents all the possible combinations of IC and VCE for a
given amplifier. For every possible value of IC, and
amplifier will have a corresponding value of VCE.)
It must be true at the same time as the transistor characteristic. Solve two condition using simultaneous equation
graphically Q-point !! What is IC(sat) and VCE(off) ?
Q-Point (Static Operation Point)
• When a transistor does not have an ac input, it will have specific dc values of IC and VCE.
• These values correspond to a specific point on the dc load line. This point is called the Q-point.
• The letter Q corresponds to the word (Latent) quiescent, meaning at rest.
• A quiescent amplifier is one that has no ac signal applied and therefore has constant dc values of IC
and VCE.
Q-Point (Static Operation Point)• The intersection of the dc bias
value of IB with the dc load line determines the Q-point.
• It is desirable to have the Q-point centered on the load line. Why?
• When a circuit is designed to have a centered Q-point, the amplifier is said to be midpoint biased.
• Midpoint biasing allows optimum ac operation of the amplifier.
DC Biasing + AC signal• When an ac signal is applied to the base of
the transistor, IC and VCE will both vary around their Q-point values.
• When the Q-point is centered, IC and VCE can both make the maximum possible transitions above and below their initial dc values.
• When the Q-point is above the center on the load line, the input signal may cause the transistor to saturate. When this happens, a part of the output signal will be clipped off.
• When the Q-point is below midpoint on the load line, the input signal may cause the transistor to cutoff. This can also cause a portion of the output signal to be clipped.
DC Biasing + AC signal
DC and AC Equivalent Circuits
RC
R1
+VCC
RE
R2
RL
vin
RC
R1
+VCC
IC
IE
RE
R2
R1//R2
rCvce
rC = RC//RL
vin
Bias Circuit DC equivalent circuit
AC equivalent circuit
AC Load Line
• The ac load line of a given amplifier will not follow the plot of the dc load line.
• This is due to the dc load of an amplifier is different from the ac load.
IC
(mA)
VCE
VCE(off) = VCC
IC(sat) = VCC/(RC+RE)
DC Load Line
IC
VCE
IC(sat) = ICQ + (VCEQ/rC)
VCE(off) = VCEQ + ICQrC
ac load lineIC
VCE
Q - point
ac load line
dc load line
AC Load Line
What does the ac load line tell you?• The ac load line is used to tell you the maximum
possible output voltage swing for a given common-emitter amplifier.
• In other words, the ac load line will tell you the maximum possible peak-to-peak output voltage (Vpp)
from a given amplifier. • This maximum Vpp is referred to as the compliance of
the amplifier.
(AC Saturation Current Ic(sat) , AC Cutoff Voltage VCE(off) )
AC Saturation Current and AC Cutoff Voltage
R1//R2
rCvce
rC = RC//RL
vin
IC
VCE
IC(sat) = ICQ + (VCEQ/rC)
VCE(off) = VCEQ + ICQrC
ac load line
Amplifier Compliance
• The ac load line is used to tell the maximum possible output voltage swing for a given common-emitter amplifier. In another words, the ac load line will tell the maximum possible peak-to-peak output voltage (VPP) from a given
amplifier. This maximum VPP is referred to as the
compliance of the amplifier. • The compliance of an amplifier is found by
determine the maximum possible of IC and VCE
from their respective values of ICQ and VCEQ.
Maximum Possible Compliance
Compliance
The maximum possible transition for VCE is equal to the
difference between VCE(off) and VCEQ. Since this transition is
equal to ICQrC, the maximum peak output voltage from the
amplifier is equal to ICQ rC. Two times this value will give
the maximum peak-to-peak transition of the output voltage:
VPP = the output compliance, in peak-to-peak
voltage
ICQ = the quiescent value of IC
rC = the ac load resistance in the circuit
VPP = 2ICQrC (A)
ComplianceWhen IC = IC(sat) , VCE is ideally equal to 0V. When I C = ICQ, VCE is at VCEQ. Note that when IC makes its maximum possible transition (from ICQ to IC(sat)), the output voltage changes by an amount equal to VCEQ. Thus the maximum peak-to-peak transition would be equal to twice this value:
• Equation (A) sets the limit in terms of VCE(off). If the value obtained by this equation is exceed, the output voltage will try to exceed VCE(off), which is not possible. This is called cutoff clipping, because the output voltage is clipped off at the value of
VCE(off).• Equation (B) sets of the limit in terms of IC(sat). If the value
obtained by this equation is exceed, the output will experience saturation clipping.
(B)VPP = 2VCEQ
Cutoff and Saturation ClippingWhen determining the output compliance for a given
amplifier, solve both equation (A) and (B). The lower of the two results is the compliance of the amplifier.
Example
• For the voltage-divider bias amplifier shown in the figure, what is the ac and dc load line. Determine the maximum output compliance.
R C4.7k
+12V
R E2.2k
R 133 k
R 210k
= 200
R L10k
Transistor Bias Circuits
Objectives
Discuss the concept of dc biasing of a transistor for linear operation
Analyze voltage-divider bias, base bias, and collector-feedback bias circuits.
Basic troubleshooting for transistor bias circuits
Introduction
For the transistor to properly operate it must be biased. There are several methods to establish the DC operating point. We will discuss some of the methods used for biasing transistors as well as troubleshooting methods used for transistor bias circuits.
The DC Operating Point
The goal of amplification in most cases is to increase the amplitude of an ac signal without altering it.
The DC Operating Point
For a transistor circuit to amplify it must be properly biased with dc voltages. The dc operating point between saturation and cutoff is called the Q-point. The goal is to set the Q-point such that that it does not go into saturation or cutoff when an a ac signal is applied.
The DC Operating PointRecall that the collector characteristic curves graphically show the relationship of collector current and VCE for different base currents. With the dc load line superimposed across the collector curves for this particular transistor we see that 30 mA of collector current is best for maximum amplification, giving equal amount above and below the Q-point. Note that this is three different scenarios of collector current being viewed simultaneously.
• Slope of the dc load line?C
CCCE
cc R
VV
R
)
1(I
The DC Operating PointWith a good Q-point established, let’s look at the effect a superimposed ac voltage has on the circuit. Note the collector current swings do not exceed the limits of operation(saturation and cutoff). However, as you might already know, applying too much ac voltage to the base would result in driving the collector current into saturation or cutoff resulting in a distorted or clipped waveform. (Example 5-1)
Voltage-Divider Bias
Voltage-divider bias is the most widely used type of bias circuit. Only one power supply is needed and voltage-divider bias is more stable( independent) than other bias types. For this reason it will be the primary focus for study.
Voltage-Divider Bias
Apply your knowledge of voltage-dividers to understand how R1 and R2 are used to provide the needed voltage to point A(base). The resistance to ground from the base is not significant enough to consider in most cases. Remember, the basic operation of the transistor has not changed.
Voltage-Divider Bias• In the case where base to ground resistance(input resistance) is
low enough to consider, we can determine it by the simplified equation RIN(base) = DCRE
• We can view the voltage at point A of the circuit in two ways, with or without the input resistance(point A to ground) considered.
Voltage-Divider Bias
• For this circuit we will not take the input resistance into consideration. Essentially we are determining the voltage across R2(VB) by the proportional method.
VB = (R2/R1 + R2)VCC
CCEDC
EDC
RRR
RV
)||(
||RV
21
2B
Voltage-Divider Bias
We now take the known base voltage and subtract VBE to find out what is dropped across RE. Knowing the voltage across RE we can apply Ohm’s law to determine the current in the collector-emitter side of the circuit. Remember the current in the base-emitter circuit is much smaller, so much in fact we can for all practical purposes we say that IE approximately equals IC.
IE≈ IC
Voltage-Divider Bias
Although we have used npn transistors for most of this discussion, there is basically no difference in its operation with exception to biasing polarities. Analysis for each part of the circuit is no different than npn transistors.
Base Bias
This type of circuit is very unstable since its changes with temperature and collector current. Base biasing circuits are mainly limited to switching applications.
DCC )(I B
BECC
R
VV
Emitter Bias• This type of circuit is
independent of making it as stable as the voltage-divider type. The drawback is that it requires two power supplies.
• Two key equations for analysis of this type of bias circuit are shown below. With these two currents known we can apply Ohm’s law and Kirchhoff's law to solve for the voltages.
• IB ≈ IE/
• IC ≈ IE ≈( -VEE-VBE)/(RE + RB/DC)
Collector-Feedback Bias
Collector-feedback bias is kept stable with negative feedback, although it is not as stable as voltage-divider or emitter. With increases of IC, less voltage is applied to the base. With less IB ,IC
comes down as well. The two key formulas are shown below.
• IB = (VC - VBE)/RB
• IC = (VCC - VBE)/(RC + RB/DC)
Summary
The purpose of biasing is to establish a stable operating point (Q-point).
The Q-point is the best point for operation of a transistor for a given collector current.
The dc load line helps to establish the Q-point for a given collector current.
The linear region of a transistor is the region of operation within saturation and cutoff.
Stability Factor
Region of operation
E – B junction
C – B junction
Cut off Reverse Biased
Reverse Biased
Active Forward Biased
Reverse Biased
Saturation Forward Biased
Forward Biased
Operating Regions
Ic
Vce
24 V0 V
Ib = 20μAIc = 2mA
Ib = 30μAIc = 4mA
Ib = 40μAIc = 6mA
Ib = 50μAIc = 8mA
Ib = 60μAIc = 10mA
Active RegionSaturation Region
Cut-off Region
Typical junction voltages
Transistor Vce sat
Vbe sat
Vbe active
Vbe cut-in
Vbe cut-off
Si 0.2 V 0.8 V 0.7 V 0.5 V 0 V
Ge 0.1 V 0.3 V 0.2 V 0.1 V -0.1 V
• In the saturation region Ic > Ib• For active region Vce > Vce(sat)
Rb
300 K Ic
Vcc = 10 V
Rc
2 K
Problem
Rb = 300 K
Calculate Ib, Ic & Vce if = 100 for the Silicon transistor. Find the region of operation
Hint
Vbe = 0.7 V
Answer
Ib = 31 A Ic=3.1mA Vce = 3.8 V Active
Rb 270 K 5.6 K
Vcc 10 V
Rc
ProblemLeakage current Io = 2 A at 250 CCalculate Rb, if the Ge transistor
remains in cut-off at 750 C HintsLeakage current doubles for every
100 CI’o = Io . 2i/10
i = t2 – t1 Vbe(cut-off) = -0.1V
Answer
Rb = 76.6 K
Vbb -5 V
Io
Rb 50 K
5.6 K
Vcc 10 V
Rc
ProblemIf Vbb = 1 V, Rb = 50 K, upto
what temperature, the transistor will remain in cut-off ? (Room temp. = 250 C
HintsFind Io’I’o = Io . 2i/10
i = t2 – t1 Find t2
Answer
t2 = 56.70 C
Vbb -1 V
Io
Ib
Ic
+Vcc 10 V
Ie
100K 2K
ProblemShow that the transistor is in
saturation regionHintsIn saturation Ic is not equal to IbVbe(sat) = 0.8 VIe = Ib + IcFind Ib & Ic
1KAnswer
Ib = 58.9 A
Ic = 3.24mA
100
Common Base Configuration
------ --- -- -- --
Vbe
_ +
E
B
Ie Ic
Ib
--
--
--- -
--
--- -
----
-----
---
--
Vcb
C
_ +
• Here the input is applied at the Emitter & the output taken from the Collector
• In this arrangement Base is common to the input & output
• This is called Common Base configuration
Input Output
Common Base Configuration
• The circuit can be re-drawn as shown, with input at Emitter & output at Collector
• Vb is obtained using Rb1 & Rb2
• This is called potential divider arrangement
Re
RcRb1
Rb2
Vcc
input
output
_ +Ib
_ +
Vee
Ie Ic
Vcc
Input Output
Re Rc
Common Emitter Configuration
• The circuit has been re-configured with input at Base & output at Collector
• The Emitter is common to input & output
• This is called Common Emitter configuration
Input
Output
_ + _ +
Ie Ic
Ib
Vee Vcc
Re
Rc
Rb1
Rb2
Vcc
Input
Output
E
B
C
Reverse Saturation current Ico
• When Emitter is open, the base & collector act as a reverse biased diode
• Since CB junction is reverse biased there will not be any Ic
• However, there will be a current due to the minority charge carriers
• This is called Reverse Saturation Current Ico
Vee_ + _ +
Ico
Vcc
Reverse Collector Saturation current Icbo
• Icbo is the leakage current that flows at the collector due to the minority charge carriers, in the common base mode
• Is the current gain in the CB mode
Vee
_+
_+
Icbo
Vcc
Ie
Reverse Collector Saturation current Iceo
• Iceo is the leakage current that flows at the collector due to the minority charge carriers, in the common emitter mode
• Is the current gain in the CE mode
Vee
_+
_+
Iceo
Vcc
Ie
1 - = Since
Ib
1 - = Ic
Icbo
1 - +
Ic Icbo(+1) + Ib =
= 1
1 - +1
i.e. Ic = Ib + Iceo where Iceo = (+1) Icbo
Ic = .Ie + Icbo
= (Ib + Ic) + Icbo
Ic (1- ) = Ib + Icbo
Stability• Temperature & Current gain variation may change
the Q point
• Stability refers to the design that prevents any
change in the Q point
• Temperature effect
• When the temperature increases it results in the
production of more charge carriers
• This increases the forward bias of the transistor
and Ib increases
Temperature effect
• When the temperature increases it results in the production
of more charge carriers
• This increases the minority charge carrier and hence the
leakage current as
Iceo = (+1) Icbo
• Icbo doubles for every 100 C
As Ic = Ib + Icbo
• The increase in the temperature increases Ic
• This in turn increases the power dissipation and again
more heat is produced
Thermal Runaway
• This increases the power dissipation• This results in more heat• Again the charge carrier increases• The whole process repeats• Ultimately Ic may become too large and burn the
transistor• This is called Thermal Runaway
Change in Vbe
• Vbe changes @ 25 mV per degree Celcius
• Ib depends on Vbe
• Ic depends on Ib
• Hence Ic changes with temperature
• This shifts the operating point
Change in
• The current gain also depends on temperature• As Ic = Ib, Ic varies with temperature• This shifts the Q point• Thermal stability should ensure that in spite of
temperature change, the selected Vce, Ic & Power max do not change
Techniques
• Stabilization technique• Resistive biasing circuits change Ib suitably and
keep Ic constant • Compensation technique• Temperature sensitive devices such as diodes,
thermistors & transistors are used to provide suitable compensation and retain the operating point without shifting
Stability Factor• It indicates the degree of change in the operating
point due to variation in temperature• There are 3 stability factors corresponding to the 3
variables – Ico, Vbe &
S Ic
Ico =
Vbe, constant
S’ Ic
Vbe =
Ico, constant
S’’ Ic
=
Ico, Vbe constant
The stability factor should be as minimum as possible
Stability Factor SIc = Ib + Iceo
= Ib + (I + ) Icbo
i.e. Ic = Ib + (I + ) Icbo
i.e. 1 = + (I + )IbIc
Icbo
Ic
i.e. 1 - IbIc
= (I + )Icbo
Ic
=S =Icbo
Ic ( I + )
1 - IbIc
i.e. Icbo
Ic =
( I + )
1 - IbIc
Design of biasing system
Fixed Bias Circuit• When Ib flows through
Rb, there will be a voltage drop across Rb
Vb = Vcc – (Ib x Rb)Ib = (Vcc – Vb) / Rb = Vcc / Rb (approx)• Supply voltage Vcc is
fixed• Hence once Rb is chosen
Ib is also fixed• Hence the name Fixed
bias circuit
Ib
Vcc
Vbe
Rb
• When collector current Ic flows through Collector load resistor Rc, there will be a voltage drop across Rc
Vc = Vcc – (Ic x Rc)
Or, Vc < Vcc
Or, Ic < Vcc / Rc
• In case Ic > Vcc / Rc, then the operating point lies in the saturation region
Ib
Vcc
Vbe
RbIc
Vce
Rc
Problem
• Design a fixed biased circuit using a silicon
transistor having
• = 100
• Vcc = 10 V
• Vce = 5 V
• Ic = 5 mA
Answer: Rc = 1 K Rb = 186 K
Problem
• A fixed bias circuit has • = 100 @ 250 C & = 125 @ 750 C • Vcc = 12 V • Rb = 100 K• Rc = 600 • Determine % change in Q point values over the
temperature range
Answer: %change in Ic = + 25% %change in Vc = - 32.5%
Stability Factor S
For the fixed Bias Circuit Ib = Vcc / Rb
S = IcIco Vbe, constant
=( I + )
1 - IbIc
IbIc. .
. = 0
S = 1 + . ..
S =( I + )
1 - (0) . ..
For Fixed Bias Circuit
Stability Factor S’
S’ IcVbe =
Ico, constant
S = - / Rb. ..
= Vcc - Vbe
Rb+ ( + 1) Icbo
= - + ( + 1) IcboRb
Vcc
Rb
Vbe
. ..
+Ib
Vbe= 0
Rb
_ 0
= Ib + ( + 1) Icbo
Ic = Ib + Iceo
For Fixed Bias Circuit
Stability Factor S’’
S’’ = Ic / . ..
Ic = Ib + Iceo S’’ Ic
=Ico, Vbe constant
For Fixed Bias Circuit
= Ib + (+1)Icbo
= Vcc - Vbe
Rb+ ( + 1) Icbo
= - + ( + 1) IcboRb
Vcc
Rb
Vbe
. .. Ic
= - + Icbo
Rb
Vcc
Rb
Vbe
= Ib + Icbo
= Ib (approx)
= Ic /
Problem
Rb = 100 K
Rc = 2 K
Vcc = 10 V
Vce = 4 V
For this emitter grounded Fixed Bias circuit with Si transistor, find the stability factor S
Answer
S = 33.3
Rb
100 K
• Ic
• 270 K • 5.6 K
Vcc = 10 V
Rc
2 K
4 V
Advantages of fixed bias circuit
• Simple circuit with minimum components
• Operating point can be fixed conveniently in the active region, by selecting appropriate value for Rb
• Hence fixed bias circuit provides flexibility in the design
Disadvantages of fixed bias circuit
• Ic increases with temperature & there is no control over it
• Hence there is poor thermal stability Ic = Ib• Hence Ic depends on • may change from transistor to transistor
• This will shift the operating point
• Hence stabilization is very poor in fixed bias circuit
• Here Rb is connected between Base & Collector
• So, Ic & Ib flow through Rc
Collector to Base Bias
Ib
Ic+Ib
Vcc
Vce
Rc
Rb Ic
Vc = Vcc – (Ic + Ib) x Rc
Also, Vc = (Ib x Rb) + Vbe
Equating the two equations
Vcc – (Ic + Ib)Rc = (Ib Rb) + Vbe
Ib
Ic+Ib
Vcc
Vce
Rc
Rb IcOr, Ib(Rc + Rb) = Vcc – IcRc - Vbe
Ib = Vcc – IcRc - Vbe
Rc + Rb . ..
Ic = ( Vcc – IcRc – Vbe)
Rc + Rb As Ic = Ib
Ib
Ic+Ib
Vcc
Vce
Rc
Rb
• Rb provides a feedback between Collector & Base
• If Ib or Ic tries to increase either due to temperature effect or due to variation in
• Voltage drop across Rc increases
• This decreases Vce
• This in turn reduces Ib, stabilizing the circuit
+12 V
100
10 K
100 K
• Problem
Calculate the values of Ic & Vce for the given circuit
Hint
Vcc = Rc(Ic + Ib) + Vce
Ic = Ib Vce = Rb Ib + Vbe
Vbe = 0.6
Answer
Ic = 1.018 mA
Vce = 1.72 V
Design a collector to base circuit for the specified conditions:
• Vcc = 15 V • Vce = 5 V • Ic = 5 mA • = 100
Hint• Vcc = Rc(Ic + Ib) + Vce• Ic = Ib• Vce = Rb Ib + Vbe
Answer
Rc = 1.98 mA Rb = 86 K
Problem
Stability Factor S
Vcc = (Ib + Ic)Rc + IbRb + Vbe S IcIco =
Vbe, constant
after differentiation
or - IcRc = Ib(Rc + Rb)
IbIc. .
. -Rc
Rc + Rb=
S =(I + )
1 - IbIc
=(I + )
1 + Rc
Rc + Rb
For Collector-Base Bias
=IcRc + Ib(Rc + Rb) + Vbe
0 = IcRc + Ib(Rc + Rb) + 0
Stabilization with changes in
• If we design our circuit such that Rc >>Rb
• Then S becomes independent of • Hence variation from transistor to transistor has no
effect on the stability
S =(1 + )
1 + Rc
Rc + Rb
S =1 +
1 + = 1
Stability Factor S’
S’ IcVbe =
Ico, constantIb =
Vcc – IcRc - Vbe
Rc + Rb
= Vcc – IcRc - Vbe
Rc + Rb
Ic
Ic+
Rc + Rb
IcRc
Rc + Rb
Vcc - Vbe=
Rc + Rb + RcIc
(Rc + Rb) Rc + Rb
Vcc - Vbe=
S’ IcVbe =
Ic =Rb + ( + 1) Rc
(Vcc – Vbe)
=Rb + ( + 1) Rc
-
For Collector-Base Bias
Stability Factor S’’
S’’ Ic
=Ico, Vbe constant
Vcc = (Ib + Ic)Rc + IbRb + Vbe
Vcc –Vbe = (Ib + Ic)Rc + IbRb
= Ib [(1 + )Rc +Rb]
Ib =. .. Vcc – Vbe
(1 + ) Rc + Rb
Ic =. .. ( Vcc – Vbe)
(1 + ) Rc + Rb
For Collector-Base Bias
. .. Ic
=[(1 + )Rc +Rb](Vcc –Vbe) - (Vcc –Vbe) Rc
[(1 + ) Rc + Rb]2
(Vcc –Vbe)[(1 + )Rc +Rb] - Rc
[(1 + ) Rc + Rb]2=
(Vcc –Vbe)(Rc +Rb)
[(1 + ) Rc + Rb]2=
= Vcc – Vbe
(1 + ) Rc + Rb
Rc + Rb
(1 + ) Rc + Rb x
= Ib(Rc + Rb)
(1 + ) Rc + Rb
= Ic(Rc + Rb)
[(1 + ) Rc + Rb] . ..
S’’
= Ic(Rc + Rb)
[(1 + ) Rc + Rb] S’’
= (Rc + Rb)
(1 + ) Rc + Rb
Ic
1+
1+
=(1 + ) Rc + Rb
Ic
1
1+
(Rc + Rb)(1+ )
= Ic
S
1+
If S is small, S’’ will also be small
Hence if we provide stability against Ico variations, it will take care of variation as well
Usually Vb is obtained using Rb & Ib
Vb = Vc – Ib Rb
Thus Ib depends on Vb & Vb depends on Ib
To avoid this anomaly, two resistors Rb1 & Rb2 have been used
Rb1 & Rb2 act as Voltage Divider circuit giving Vb, irrespective of Ib
Ib1 Ic270 K 5.6 K
Vcc
Re
RcRb1
Rb2
Ib2
Ib
Ie
Voltage Divider Bias
• Rb1 is called Base Bias Resistor
• Rb2 is called Base Bleeder Resistor
• Vb is obtained based on the ratio of Rb1 and Rb2
Ib1 Ic270 K 5.6 K
Vcc
Re
RcRb1
Rb2
Ib2
Ib
Ie Rb2Vb = Vcc Rb1 + Rb2
Rest of the equations remain the same
Vc = Vcc – Ic Rc
Vb = Ve + Vbe
Ve = Ie Re
Ib1 Ic270 K 5.6 K
Vcc
Re
RcRb1
Rb2
Ib2
Ib
Ie
Problem
For the Si transistor, if is
100, find
Vce & Ic
Hints
Find Vb, Ve, Ie, Ib
Answer
Ic = 5.2 mA
Vce = 2.16 V
+10 V
Re 500
Rc
1 K
Rb1 10 K
Rb 2 5 K
We can draw the Thevenin
Equivalent Circuit for the
base circuit
VT = Vb &
R = Rb1 II Rb2Ib1 Ic
270 K 5.6 K
Vcc
Re
RcRb1
Rb2
Ib2
Ib
Ic5.6 K
Vcc
Re
Rc
Rb2
VT Ie
R
Ib
Vb = IbRb +Vbe + IeRe
S IcIco =
Vbe, constant
0 = IbRb + 0 + IbRe + IcRe
i.e. Ib(Rb + Re) = - IcRe
IbIc. .
. -Re
Rb + Re= S =
(I + )
1 - IbIc
=(I + )
1 + Re
Re + Rb
where Rb = Rb1 ll Rb2
Stability Factor SFor Voltage Divider Bias
= IbRb +Vbe + (Ib + Ic)Re
Differentiating,
• In the above equation, if Rb << Re, then S becomes 1
Rb = Rb1 ll Rb2
• Hence either Rb1 or Rb2 must be << Re
• Since Vb << Vcc, Rb2 is kept small wrt Rb1
S =(I + )
1 + Re
Re + Rb
• Re cannot be increased beyond a limit, as it will affect Ic and hence the Q point
• If Rb-Re ratio is fixed, and if Rb >> Re, S increases with
• Thus stability decreases with increasing
S =(I + )
1 + Re
Re + Rb
S =(I + )
1 + 1
1 + Rb/Re
S = (I + )
• If Rb << Re, then S becomes independent of
• Stability factor S for Voltage Divider circuit is less compared to other circuits
• Hence it is preferred over other circuits
S =(I + )
1 + Re
Re + Rb
S =(I + )
1 + 1
1 + Rb/Re
S = I
Problem For the Ge transistor, if is
50, find Vce & Ic Find Ib,Vce, Ic & S
Hint Vbe = 0.2 V
Answer Ib = 76.3 uA Vce = 11.98 V Ic = 3.81 mA S = 25.14
+20 V
Re 100
Rc 2 K
Rb1 100 K
Rb2 5 K
Problem
For the Si transistor, if is
100 & Ic = 2 mA find
Re,Vce, & S
Answer
Re = 149 Vce = 7.7 V
S = 24.25
+20 V
Re
Rc 2 K
Rb1 50 K
Rb2 5 K
Problem
• Design a voltage divider bias circuit for the given specifications:
• Vcc = 12 V, Vce = 6 V, Ic = 1 mA, S = 20, = 100 & Ve = 1 V
Answer:
Rb1= 150 K , Rb2 = 27 K, Rc = 4.7 K , Re = 1 K
Stability Factor S’
S’ IcVbe =
Ico, constant
S’ IcVbe
= =Rb + ( + 1) Re
-
= Ib(Rb + Re) + Vbe + IcRe
= Ic / (Rb +Re) + Vbe + IcRe
Or, Vb = Ic(Rb +Re) + Vbe + IcRe
= Ic[Rb +( + 1)Re] + Vbe
Differentiating, 0 = Ic[Rb +( + 1)Re] + Vbe
For Voltage Divider Bias
Vb = IbRb +Vbe + IeRe
= IbRb + Vbe + (Ib + Ic)Re
Or, Vbe = - Ic [Rb +( + 1)Re]
Stability Factor S’’
= Ib(Rb + Re) + Vbe + IcRe
= Ic / (Rb +Re) + Vbe + IcRe
Or, Vb = Ic(Rb +Re) + Vbe + IcRe
Differentiating,
S’’ Ic
=Ico, Vbe constant
Or, (Vb – Vbe) = Ic(Rb +Re) + IcRe
(Vb – Vbe) = Ic(Rb +Re) + IcRe + Ic Re
(Vb – Vbe – IcRe) = Ic[Rb + Re+ Re]
. .. Ic
=S’’ =
Vb – Vbe - IcRe
Rb + Re(1+ )
Vb = IbRb +Vbe + IeRe
For Voltage Divider Bias
Hence Rb / Re must be small to make S’’ smaller
Ic
=S’’ =
Vb – Vbe - IcRe
Rb + Re(1+ )
=Vb – Vbe - IeRe
Rb + Re(1+ )As Ie = Ic
=Ib Rb
Rb + Re(1+ )
=Ib
1 +(Re/Rb)(1+ )
Ib1 Ic270 K 5.6 K
Vcc
Re
RcRb1
Rb2
Ib2
Ib
• In this circuit Re provides Self bias
• When Ib or Ic tries to increase, Ie increases
• This produces more drop across Re & increases Ve
• This reduces Vbe which is Vb – Ve
• This in turn reduces Ib and hence Ic
• Thus Re provides a negative feed back and improves the stability
Self Bias
Bias Compensation• The biasing circuits seen so far provide stability of
operating point for any change in Ico, Vbe or
• The collector- base bias & emitter bias circuits provide negative feedback & make the circuit stable, but the gain falls down
• In such cases it is necessary to use compensation techniques
Here diode D has been connected as shown
It is given forward bias through Vdd
The diode D is identical to the BE junction of the transistor
The charge carriers will increase in the BE jn. due to temperature or other variations
• Diode Compensation Technique
Rb 270 K 5.6 K
Vcc
Rc
Rd
+
-
Re
Vdd D
Since diode D has similar properties, its charge carrier also increases, for any change in the parameters
Thus the increase in current in the BE junction is compensated by the current flow through the diode in the reverse direction.
Rb 270 K 5.6 K
Vcc
Rc
Rd
+
-
Re
Vdd D
Another techniqueHere the diode D has been
connected in the bleeder path
When there is increase in current in the BE junction due to parameter changes, current through D also increases by the same amount
Rb1 270 K 5.6 K
Vcc
Rc
ReRb2
D
Ib1
Ib2
This increases Ib1, produces more
drop across Rb1& reduces Vb
As Vb decreases, Ib falls down
Thus the transistor currents are
arrested and not allowed to
increase
Thus diode D provides suitable
compensation
Rb1 270 K 5.6 K
Vcc
Rc
ReRb2
D
Here a Negative Temperature Coefficient Resistor has been used
As temperature increases, its resistance decreases
This increases Ib1 & voltage drop across Rb1
This decreases Vb and hence Ib & Ic, thus keeping the circuit stable.
Thermistor Compensation
270 K 5.6 K
Vcc
Re
RcRb1
NTC
Ib
Ib1
Ib2
Here a Positive Temperature Coefficient Resistor has been used
As temperature increases, its resistance increases
This increases the voltage drop across Rb1(PTC)
This reduces Vb and Ib, thus keeping the circuit stable.
Sensitor Compensation
270 K 5.6 K
Vcc
Re
Rc
Rb2
PTC
Ib
Rb1
Re provides self bias
Vb is fixed depending on
the ratio of Rb1 & Rb2 &
the value of Vcc
Ve = Vb - Vbe
Vbe is fixed for a transistor
Hence Ve is fixed &
Ie = Ve / Re is also fixed
Hence it acts as a constant
current circuit
5.6 K
Vcc
Re
RcRb1
Rb2
Constant Current circuit
270 K 5.6 K
-20 V
Re 2K2
Rb1
Problem For the given Si transistor
find the constant current I
Answer I = 4.22 mA
Rb2 4K7
I
FET Biasing
Introduction• For the JFET, the relationship between input and
output quantities is nonlinear due to the squared term in Shockley’s equation.
• Nonlinear functions results in curves as obtained for transfer characteristic of a JFET.
• Graphical approach will be used to examine the dc analysis for FET because it is most popularly used rather than mathematical approach
• The input of BJT and FET controlling variables are the current and the voltage levels respectively
JFETs differ from BJTs:
• Nonlinear relationship between input (VGS) and output (ID)
• JFETs are voltage controlled devices, whereas BJTs are current controlled
Introduction
Common FET Biasing Circuits• JFET
– Fixed – Bias – Self-Bias – Voltage-Divider Bias
• Depletion-Type MOSFET– Self-Bias– Voltage-Divider Bias
• Enhancement-Type MOSFET– Feedback Configuration– Voltage-Divider Bias
Introduction
General Relationships• For all FETs:
• For JFETs and Depletion-Type MOSFETs:
• For Enhancement-Type MOSFETs:
AIG 0
SD II
2
P
GSDSSD )
V
V(1II
2)( TGSD VVkI
Fixed-Bias Configuration• The configuration includes the ac levels Vi and Vo and the
coupling capacitors.• The resistor is present to ensure that Vi appears at the input to
the FET amplifier for the AC analysis.
Fixed-Bias Configuration• For the DC analysis,
• Capacitors are open circuits and • The zero-volt drop across RG permits replacing RG by a short-circuit
AIG 0 VRARIV GGGRG 0)0(
Fixed-Bias Configuration
Investigating the input loop
• IG=0A, therefore
VRG=IGRG=0V
• Applying KVL for the input loop,
-VGG-VGS=0
VGG= -VGS
• It is called fixed-bias configuration due to VGG is a
fixed power supply so VGS is fixed
• The resulting current,2)1(
P
GSDSSD V
VII
• Investigating the graphical approach.• Using below tables, we can draw the graph
VGS ID
0 IDSS
0.3VP IDSS/2
0.5 IDSS/4
VP 0mA
• The fixed level of VGS has been superimposed as a
vertical line at
• At any point on the vertical line, the level of VG is -
VGG--- the level of ID must simply be determined on this
vertical line.
• The point where the two curves intersect is the common
solution to the configuration – commonly referrers to as
the quiescent or operating point.
• The quiescent level of ID is determine by drawing a
horizontal line from the Q-point to the vertical ID axis.
GGGS VV
• Output loop
DDDDDS RIVV
VVS 0
SDDS VVV
SDSD VVV 0SV
DSD VV
SGGS VVV
SGSG VVV 0SV
GSG VV
Example
• Determine VGSQ, IDQ, VDS, VD, VG, VS
Exercise• Determine IDQ, VGSQ, VDS, VD, VG and VS
Self Bias Configuration
• The self-bias configuration eliminates the need for two dc supplies.
• The controlling VGS is now determined by the voltage across the resistor RS
• For the indicated input loop:
• Mathematical approach:
rearrange and solve.
SDGS RIV
2
2
1
1
P
SDDSSD
P
GSDSSD
V
RIII
V
VII
• Graphical approach– Draw the device transfer characteristic– Draw the network load line
• Use to draw straight line.• First point,• Second point, any point from ID = 0 to ID = IDSS. Choose
– the quiescent point obtained at the intersection of the straight line plot and the device characteristic curve.
– The quiescent value for ID and VGS can then be determined and used to find the other quantities of interest.
SDGS RIV 0,0 GSD VI
2
2
SDSSGS
DSSD
RIV
thenI
I
• For output loop– Apply KVL of output loop– Use ID = IS
RDDDSDSD
SDS
DSDDDDS
VVVVV
RIV
RRIVV
)(
Example• Determine VGSQ, IDQ,VDS,VS,VG and VD.
Example
• Determine VGSQ, IDQ, VD,VG,VS and VDS.
Voltage-Divider Bias• The arrangement is the same as BJT but the DC
analysis is different• In BJT, IB provide link to input and output circuit, in
FET VGS does the same
Voltage-Divider Bias• The source VDD was separated into two equivalent sources to
permit a further separation of the input and output regions of the network.
• IG = 0A ,Kirchoff’s current law requires that IR1= IR2 and the series
equivalent circuit appearing to the left of the figure can be used to find the level of VG.
21
DD2G
RR
VRV
SDGGS
RSGSG
RIVV
VVV
0
Voltage-Divider Bias
• VG can be found using the voltage divider rule :
• Using Kirchoff’s Law on the input loop:
• Rearranging and using ID =IS:
• Again the Q point needs to be established by
plotting a line that intersects the transfer curve.
Procedures for plotting
1. Plot the line: By plotting two points: VGS = VG, ID =0 and VGS = 0,
ID = VG/RS
2. Plot the transfer curve by plotting IDSS, VP and calculated values of ID.
3. Where the line intersects the transfer curve is the Q point for the
circuit.
• Once the quiescent values of IDQ and VGSQ are
determined, the remaining network analysis can be found.
• Output loop:
2121 RR
VII DD
RR
)( SDDDDDDS RIRIVV
DDDDD RIVV
SDS RIV
Effect of increasing values of RS
Example
• Determine IDQ, VGSQ, VD, VS, VDS and VDG.
Example
• Determine IDQ, VGSQ, VDS, VD and VS
• Depletion-type MOSFET bias circuits are similar to JFETs. The only difference is that the depletion-Type MOSFETs can operate with positive values of VGS and with ID values that exceed IDSS.
Depletion-Type MOSFETs
The DC Analysis Same as the FET calculations
Plotting the transfer characteristics of the device Plotting the at a point that VGS exceeds the 0V or more
positive values Plotting point when VGS=0V and ID=0A The intersection between Shockley characteristics and linear
characteristics defined the Q-point of the MOSFET The problem is that how long does the transfer
characteristics have to be draw? We have to analyze the input loop parameter relationship. As RS become smaller, the linear characteristics will be in
narrow slope therefore needs to consider the extend of transfer characteristics for example of voltage divider MOSFET,
The bigger values of VP the more positive values we should draw for the transfer characteristics
SDGGS
RSGSG
RIVV
VVV
0
Depletion-Type MOSFETs
•Analyzing the MOSFET circuit for DC analysis
How to analyze dc analysis for the shown network? It is a …. Type network Find VG or VGS
Draw the linear characteristics
Draw the transfer characteristics
Obtain VGSQ and IDQ from the graph intersection
1. Plot line for VGS = VG, ID = 0 and ID = VG/RS, VGS = 0
2. Plot the transfer curve by plotting IDSS, VP and calculated values
of ID.
3. Where the line intersects the transfer curve is the Q-point.
Use the ID at the Q-point to solve for the other variables in the
voltage-divider bias circuit. These are the same calculations as used by a JFET circuit.
• When RS change…the linear characteristics will change..
1. Plot line for VGS = VG, ID = 0 and ID = VG/RS, VGS = 0
2. Plot the transfer curve by plotting IDSS, VP and calculated values
of ID.
3. Where the line intersects the transfer curve is the Q-point.
Use the ID at the Q-point to solve for the other variables in the
voltage-divider bias circuit. These are the same calculations as used
by a JFET circuit.
• The transfer characteristic for the enhancement-type MOSFET is very different from that of a simple JFET or the depletion-type MOSFET.
Enhancement-Type MOSFET
• Transfer characteristic for E-MOSFET
and
2)( )( ThGSGSD VVkI
2)()(
)(
)( ThGSonGS
onD
VV
Ik
Feedback Biasing Arrangement
• IG =0A, therefore VRG = 0V
• Therefore: VDS = VGS
• Which makes DDDDGS RIVV
1. Plot the line using VGS = VDD, ID = 0 and ID = VDD / RD and VGS =
0
2. Plot the transfer curve using VGSTh , ID = 0 and VGS(on), ID(on); all
given in the specification sheet.
3. Where the line and the transfer curve intersect is the Q-Point.
4. Using the value of ID at the Q-point, solve for the other variables
in the bias circuit.
Feedback Biasing Q-Point
DC analysis step for Feedback Biasing Enhancement type MOSFET
Find k using the datasheet or specification given;
ex: VGS(ON),VGS(TH)
Plot transfer characteristics using the formula
ID=k(VGS – VT)2. Three point already defined that is ID(ON), VGS(ON) and VGS(TH)
Plot a point that is slightly greater than VGS Plot the linear characteristics (network bias line) The intersection defines the Q-point
Example
• Determine IDQ and VDSQ for network below
Again plot the line and the transfer curve to find the Q-point.
Using the following equations: 21
DD2G
RR
VRV
)( DSDDDDS
SDGGS
RRIVV
RIVV
Input loop :
Output loop:
Voltage-Divider Biasing
1. Plot the line using VGS = VG = (R2VDD)/(R1 + R2), ID = 0 and ID = VG/RS and VGS = 0
2. Find k
3. Plot the transfer curve using VGSTh, ID = 0 and VGS(on), ID(on); all given in the specification sheet.
4. Where the line and the transfer curve intersect is the Q-Point.
5. Using the value of ID at the Q-point, solve for the other variables in the bias circuit.
Voltage-Divider Bias Q-Point
Example
• Determine IDQ and VGSQ and VDS for network below
• =• = • -
• -
• =• -• =
• - • + • )• (
• =• = • -
• +
• = • - • )• (• +
• =• =
• -• )• (• +• + • -
• =• =
• =• -• =• =• = • -
• =• -• = • -
• =• +• -• =• = • - • +• ( • )
• =• = • -
• =• =
• +• -
Troubleshooting
N-channel VGSQ will be 0V or negative if properly checked
Level of VDS is ranging from 25%~75% of VDD. If 0V indicated, there’s problem
Check with the calculation between each terminal and ground. There must be a reading, RG will be excluded
For p-channel FETs the same calculations and graphs are used, except that the voltage polarities and current directions are the opposite. The graphs will be mirrors of the n-channel graphs.
P-Channel FETs
• Voltage-Controlled Resistor
• JFET Voltmeter
• Timer Network
• Fiber Optic Circuitry
• MOSFET Relay Driver
Practical Applications
Thanking You