Unit – 4
Avalanche breakdown
Q1) Determine the values of VCC RC and RB of a fixed bias configuration for a given load line and defined Q point.
A1)
Q2) A npn silicon transistor has VCC = 6 V and the collector load RC = 2.5 kΩ. Find: (i) The maximum collector current that can be allowed during the application of signal for faithful amplification. (ii) The minimum zero signal collector current required.
A2)
Collector supply voltage, VCC = 6 V
Collector load, RC = 2.5 kΩ
(i) We know that for faithful amplification, VCE should not be less than 1V for silicon transistor.
∴ Max. Voltage allowed across RC = 6 − 1 = 5 V
∴ Max. Allowed collector current = 5 V/RC = 5 V/2.5 kΩ = 2 mA
Thus, the maximum collector current allowed during any part of the signal is 2 mA. If the collector current is allowed to rise above this value, VCE will fall below 1 V. Consequently, value of β will fall, resulting in unfaithful amplification.
(ii) During the negative peak of the signal, collector current can at the most be allowed to become zero. As the negative and positive half cycles of the signal are equal, therefore, the change in collector current due to these will also be equal but in opposite direction.
∴ Minimum zero signal collector current required = 2 mA/2 = 1 mA
During the positive peak of the signal [point A in Fig. 1(ii)], iC = 1 + 1 = 2mA
And during the negative peak (point B), iC = 1 − 1 = 0 mA
Q3) A transistor employs a 4 kΩ load and VCC = 13V. What is the maximum input signal if β = 100? Given Vknee = 1V and a change of 1V in VBE causes a change of 5mA in collector current.
A3)
Collector supply voltage, VCC = 13 V
Knee voltage, Vknee = 1 V
Collector load, RC = 4 kΩ
∴ Max. Allowed voltage across RC = 13 − 1 = 12 V
∴ Max. Allowed collector current, iC =12 V /RC = 12 V/ 4 KΩ = 3 mA
Maximum base current, iB = iC / β = 3 mA / 100 = 30 μA
Now collector-current / Base voltage (signal voltage) = 5 mA/V
∴Base voltage (signal voltage) = Collector current / (5 mA/V) = 3 mA /(5 mA/V) = 600 mV
Q4) Fig. (i) shows biasing with base resistor method. (i) Determine the collector current IC and collector-emitter voltage VCE. Neglect small base-emitter voltage. Given that β = 50. (ii) If RB in this circuit is changed to 50 kΩ, find the new operating point.
A4)
In the circuit shown in Fig. (i), biasing is provided by a battery VBB (= 2V) in the base circuit which is separate from the battery VCC (= 9V) used in the output circuit.
The same circuit is shown in a simplified way in Fig. (ii). Here, we need show only the supply voltages, + 2V and +9V. It may be noted that negative terminals of the power supplies are grounded to get a complete path of current.
IB RB + VBE = 2
IB = 20A
IC = IB = 50x20A= 1mA
IC RC + VCE = 9
VCE = 9- (1mA x 2000) = 7V
When RB is made equal to 50k
IC = IB = 50x40A= 2mA
VCE = 9- (2mA x 2000) = 5V
So, the operating point is 5V and 2mA
Q5) Fig. (i) shows that a silicon transistor with β = 100 is biased by base resistor method. Draw the d.c. load line and determine the operating point. What is the stability factor?
A5)
Here, VCC = 6 V, RB = 530 kΩ, RC = 2 kΩ
D.C. Load line
Referring to Fig. (i), VCE = VCC − ICRC
When IC = 0,
VCE = VCC = 6 V. This locates the first point B (OB = 6V) of the load line on collector-emitter voltage axis as shown in Fig. (ii).
When VCE = 0,
IC = VCC/RC = 6V/2 kΩ = 3 mA.
This locates the second point A (OA = 3mA) of the load line on the collector current axis. By joining points A and B, d.c. Load line AB is constructed as shown in Fig. (ii).
Operating point Q
As it is a silicon transistor, therefore, VBE = 0.7V.
IB RB +VBE =VCC
IB = (6-0.7)/530x103 =10A
IC = IB = 100x10= 1mA
VCE = 6- (1mA x 2000) = 4V
The operating point is 4V, 1mA.
The stability factor is given by +1 = 100+1 =101
Q6) Design base resistor bias circuit for a CE amplifier such that operating point is VCE = 8V and IC = 2 mA. You are supplied with a fixed 15V d.c. supply and a silicon transistor with β = 100. Take base-emitter voltage VBE = 0.6V. Calculate also the value of load resistance that would be employed.
Fig. Shows CE amplifier using base resistor method of biasing.
A6)
VCC = 15v
β = 100
VBE = 0.6V
VCE = 8V, IC = 2 mA.
VCC = VCE + IC RC
15 = 8+ 2mAxRC
RC = 3.5k
IC = IB
IB = 2/100 =0.02mA
VCC = IB RB + VBE
RB = (15-0.6)/ (0.02x10-3) = 720k
Q7) In base bias method, how Q-point is affected by changes in VBE and ICBO?
A7)
In addition to being affected by change in β, the Q-point is also affected by changes in VBE and ICBO in the base bias method.
(i) Effect of VBE:
The base-emitter-voltage VBE decreases with the increase in temperature (and vice-versa). The expression for IB in base bias method is given by;
IB = VCC – VBE/RB
It is clear that decrease in VBE increases IB. This will shift the Q-point (IC = βIB and VCE = VCC – IC RC). The effect of change in VBE is negligible if VCC >> VBE (VCC at least 10 times greater than VBE).
(ii) Effect of ICBO:
The reverse leakage current ICBO has the effect of decreasing the net base current and thus increasing the base voltage. It is because the flow of ICBO creates a voltage drop across RB that adds to the base voltage as shown in Fig. Therefore, change in ICBO shifts the Q-point of the base bias circuit.
However, in modern transistors, ICBO is usually less than 100 nA and its effect on the bias is negligible if VBB >> ICBO RB.
Q8) For figure below is a resistor transistor circuit. The device has the characteristics as shown below. Find VCC, RC and RB?
A8)
The DC Line voltage VCC = 20V
Maximum IC = VCC/RC
RC = 20/8x10-3=2.5k
IB = VCC – VBE/RB
RB = 20-0.7/40x10-6 = 482.5k
Q9) A 5.0V stabilized power supply is required to be produced from a 12V DC power supply input source. The maximum power rating PZ of the zener diode is 2W. Using the zener regulator circuit above calculate:
a). The maximum current flowing through the zener diode.
b). The minimum value of the series resistor, RS
c). The load current IL if a load resistor of 1kΩ is connected across the zener diode.
d). The zener current IZ at full load.
A9)
a). The maximum current flowing through the zener diode.
Maximum current = Watts/ Voltage =2W/5V =400mA
b). The minimum value of the series resistor, RS
= 17.5 Ω
c). The load current IL if a load resistor of 1kΩ is connected across the zener diode.
d). The zener current IZ at full load.
Iz =Is -Il =440mA – 5mA = 395mA
Q10) In a CB IE= 2mA, IC=1.5mA. Calculate IB?
A10)
IE =IB+IC
2= IB+1.5
IB=0.5mA
Q11) In a CB current amplification factor is 0.9. If emitter current is 1.2mA. Determine the value of base current?
A11)
α = 0.9
IE =1.2mA
α = IC/ IE
IC = α IE =0.9 x 1.2 = 1.08mA
IE =IB+IC
1.2= IB+1.08
IB= 0.12mA
Q12) In a CB connection IC=1.0mA and IB= 0.02mA. Find the value of current amplification factor?
A12)
IE =IB+IC =1+0.02 = 1.02mA
α = IC/ IE
α = 1.0/1.02 = 0.98
Q13) In a CB connection the emitter current is 0.98mA. If the emitter circuit is open the collector current becomes 40A. Find total collector current. α =0.92
A13)
ICBO=40A
IC = α IE+ICBO
= (0.92 x 0.98x10-3) + 40x10-6
IC =0.94mA
Q14) In a common base connection, α = 0.95. The voltage drop across 3 kΩ resistance which is connected in the collector is 2.5 V. Find the base current.
A14)
IC = 2.5/3000 = 0.83mA
α = IC/ IE
IE = IC/α =0.83/0.95=0.87mA
IE =IB+IC
0.87 =IB+0.83
IB=0.04mA
Q15) Find the value of β if (i) α = 0.9 (ii) α = 0.98 (iii) α = 0.99.
A15)
= α/1- α = 0.9/1-0.9 = 9
= α/1- α = 0.98/1-0.98 = 49
= α/1- α = 0.99/1-0.99 = 99
Q16) The collector leakage current in a transistor is 200 μA in CE arrangement. If now the transistor is connected in CB arrangement, what will be the leakage current? Given that β = 120.
A16)
ICEO=200 μA
= 120
α = /1+= 120/121=0.99
ICEO=ICBO/1- α
ICBO= 1.6 μA
Q17) For a certain transistor, IB = 18 μA; IC = 2 mA and β = 60. Calculate ICBO.
A17)
IC = IB+ICEO
ICEO= IC - IB= 2x10-3-(60x18x10-6) = 0.92mA
α = /1+= 60/61=0.98
ICBO= (1- α) ICEO = (1-0.98)x 0.92=15.08 μA
Q18) Compare CB CE and CC configuration?
A18)
Parameters | Common-Emitter (CE) Amplifier | Common-Base(CB) Amplifier | Common-Collector (CC) Amplifier |
Input resistance | Moderate | Low | High |
Output resistance | Low | ||
Voltage gain | High | High | About 1 |
Current gain | High β | Low, about 1 | High(1+β) |
Power gain | High | Moderate | Low |
Phase shift | 180° | 0° | 0° |
Q19) Draw and explain input and output characteristics of CB configuration?
A19)
Input Characteristic Curve
Fig: Input Characteristic Curve (Ref. 2)
- It is the relation between the input current IE to the input voltage VBE for various levels of output voltage VCB.
- It is also known as driving point characteristics.
Output Characteristic Curve
Fig: Output Characteristic Curve (Ref. 2)
- It is the relation between the output current IC to the output voltage VCB for various levels of input current IE.
- It is also known as collector set of characteristics.
- It has three basic regions:
- Active Region
Here, base-emitter junction is forward biased and collector-base junction is reverse biased.
As input current IE increases above zero, output current IC increases to a magnitude equal to IE as determined by the basic transistor current relationship.
So, the first approximation determined by the curve is
IC ≈ IE
2. Cut-off Region
It is defined as the region where the collector current IC is equal to 0A.
Here, the base-emitter junction and the collector-base junction both are in reverse bias.
3. Saturation Region
It is the region that lies towards the left of VCB = 0V.
Here, the base-emitter junction and the collector-base junction both are in forward bias.
Q20) Explain difference between avalanche and Zener breakdown?
A20)
Zener Breakdown | Avalanche Breakdown |
The process in which the electrons move across the barrier from the valence band of p-type material to the conduction band of n-type material is known as Zener breakdown. | The process of applying high voltage and increasing the free electrons or electric current in semiconductors and insulating materials is called an avalanche breakdown. |
This is observed in Zener diodes having a Zener breakdown voltage of 5 to 8 volts. | This is observed in Zener diode having a Zener breakdown voltage greater than 8Volts. |
The valence electrons are pulled into conduction due to the high electric field in the narrow depletion region. | The valence electrons are pushed to conduction due to the energy imparted by accelerated electrons, which gain their velocity due to their collision with other atoms. |
The increase in temperature decreases the breakdown voltage. | The increase in temperature increases the breakdown voltage. |
The VI characteristics of a Zener breakdown has a sharp curve. | The VI characteristics curve of the avalanche breakdown is not as sharp as the Zener breakdown. |
It occurs in diodes that are highly doped. | It occurs in diodes that are lightly doped. |