ece transistors ppt
TRANSCRIPT
GROUP MEMBERS:-1)ALOK MISHRA(D-46)2)VIKRAM SINGH MAURYA(D-47)3)ARTH MATARKAR(D-48)4)RISHI RAJ(D-49)5)NISHANT(D-50)
CONTENTS1) Introduction
2) Transistor Theory
3) Naming the Transistor Terminal
4) Transistor Action
5) Transistor Symbol
INTRODUCTION
What is a transistor?
A transistor is a 3 terminal electronic device made of semiconductor material.
Transistors have many uses, including amplification, switching, voltage regulation, and the modulation of signals
Before transistors were invented, circuits used vacuum tubes:
Fragile, large in size, heavy, generate large quantities of heat, require a large amount of power The first transistors were created at Bell Telephone Laboratories in 1947
William Shockley, John Bardeen, and Walter Brattain created the transistors in and effort to develop a technology that would overcome the problems of tubes The first patents for the principle of a field effect transistor were
registered in 1928 by Julius Lillenfield. Shockley, Bardeen, and Brattain had referenced this material in their
work
The word “transistor” is a combination of the terms “transconductance” and “variable resistor” Today an advanced microprossesor can have as many as 1.7 billion
transistors.
HISTORY
What Are Diodes Made Out Of?
• Silicon (Si) and Germanium (Ge) are the two most common single elements that are used to make Diodes. A compound that is commonly used is Gallium Arsenide (GaAs), especially in the case of LEDs because of it’s large bandgap.
• Silicon and Germanium are both group 4 elements, meaning they have 4 valence electrons. Their structure allows them to grow in a shape called the diamond lattice.
• Gallium is a group 3 element while Arsenide is a group 5 element. When put together as a compound, GaAs creates a zincblend lattice structure.
• In both the diamond lattice and zincblend lattice, each atom shares its valence electrons with its four closest neighbors. This sharing of electrons is what ultimately allows diodes to be build. When dopants from groups 3 or 5 (in most cases) are added to Si, Ge or GaAs it changes the properties of the material so we are able to make the P- and N-type materials that become the diode.
Si+4
Si+4
Si+4
Si +4
Si+4
Si+4
Si+4
Si+4
Si+4
The diagram above shows the 2D structure of the Si crystal. The light green lines represent the electronic bonds made when the valence electrons are shared. Each Si atom shares one electron with each of its four closest neighbors so that its valence band will have a full 8 electrons.
N-Type Material:-
When extra valence electrons are introduced into a material such as silicon an n-type material is produced. The extra valence electrons are introduced by putting impurities or dopants into the silicon. The dopants used to create an n-type material are Group V elements. The most commonly used dopants from Group V are arsenic, antimony and phosphorus. The 2D diagram to the left shows the extra electron that will be present when a Group V dopant is introduced to a material such as silicon. This extra electron is very mobile.
+4+4
+5
+4
+4+4+4
+4+4
P-Type Material:-
P-type material is produced when the dopant that is introduced is from Group III. Group III elements have only 3 valence electrons and therefore there is an electron missing. This creates a hole (h+), or a positive charge that can move around in the material. Commonly used Group III dopants are aluminum, boron, and gallium.The 2D diagram to the left shows the hole that will be present when a Group III dopant is introduced to a material such as silicon. This hole is quite mobile in the same way the extra electron is mobile in a n-type material.
+4+4
+3
+4
+4+4+4
+4+4
P-N Junction DiodesForward Bias:
Current flows from P to N
Reverse Bias:No Current flowsExcessive heat can cause dopants in a semiconductor device to migrate in either direction over time, degrading diodeEx: Dead battery in car from rectifier short Ex: Recombination of holes and electrons cause rectifier open circuit and prevents car alternator form charging battery
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●Practical Diode Circuit• Diode charges
capacitor.
• The diode is assumed ideal. It will only conduct when vI is more than vo
TRANSISTOR THEORY
BJT Structure - Discrete
Early BJTs were fabricated using alloying - an complicated and unreliable process.The structure contains two p-n diodes, one between the base and the emitter, and one between the base and the collector.
A bipolar transistor essentially consists of a pair of PN Junction diodes that are joined back-to-back. There are therefore two kinds of BJT, the NPN and PNP varieties. The three layers of the sandwich are conventionally called the Collector, Base, and Emitter.
BJTs are usually constructed vertically›Controlling depth of the emitter’s n doping sets the base width
np
n
E B C
.The Bipolar Junction Transistor
The transistor is a versatile device usually configured to perform as a switch or as an amplifier. The bipolar junction transistor (BJT) is the most common type and has three leads:
BaseCollector
Emitter
PNP Transistor
BaseCollector
Emitter
NPN Transistor
In a transistor, the flow of current from the collector to the emitter is controlledby the amount of current flowing into the base of the transistor. If no currentflows into the base, no current will flow from the collector to the emitter (it actslike an open switch). If current flows into the base, then a proportional amountof current flows from the collector to the emitter (somewhat like a closed switch).
1
2
3
1
3
2
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The First BJT
Transistor Size (3/8”L X 5/32”W X 7/32”H)No Date Codes. No Packaging.
BJT Transistors
BJT (Bipolar Junction Transistor)› npn
Base is energized to allow current flow
› pnp Base is connected to a lower potential to allow current
flow
3 parameters of interest› Current gain (β)› Voltage drop from base to emitter when VBE=VFB
› Minimum voltage drop across the collector and emitter when transistor is saturated
npn BJT Transistors
High potential at collector
Low potential at emitter
Allows current flow when the base is given a high potential
pnp BJT Transistors
High potential at emitter
Low potential at collector
Allows current flow when base is connected to a low potential
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Schematic representation of pnp and npn BJTs
Emitter is heavily doped compared to collector. So, emitterand collector are not interchangeable.
The base width is small compared to the minority carrierdiffusion length. If the base is much larger, then this willbehave like back-to-back diodes.
Field-effect transistors (FETs) are probably the simplest form of transistor
widely used in both analogue and digital applicationsthey are characterised by a very high input resistance and small physical size, and they can be used to form circuits with a low power consumptionthey are widely used in very large-scale integrationtwo basic forms:
insulated gate FETsjunction gate FETs
An Overview of Field-Effect Transistors
Many forms, but basic operation is the same
a voltage on a control input produces an electric field that affects the current between two other terminalswhen consideringamplifiers we lookedat a circuit using a‘control device’a FET is a suitablecontrol device
FET Transistors
Analogous to BJT Transistors
FET Transistors switch by voltage rather than by current
S
G
D
FET Transistors – How it works
The “Field Effect” The resulting field at the plate causes electrons to
gather As an electron bridge forms current is allowed to
flow
Semi-conductor
Plate
Modern Transistors
NAMING OF TRANSISTOR
TERMINAL
PNP transistor symbol and crystal structure.
NPN transistor symbol and crystal structure.
TRANSISTOR ACTION
Terminals & Operations
Three terminals:Base (B): very thin and lightly doped central region (little recombination).Emitter (E) and collector (C) are two outer regions sandwiching B.
Normal operation (linear or active region):B-E junction forward biased; B-C junction reverse biased.The emitter emits (injects) majority charge into base region and because the base very thin, most will ultimately reach the collector.The emitter is highly doped while the collector is lightly doped.The collector is usually at higher voltage than the emitter.
WORKING OF TRANSISTOR
The emitter base junction of a transistor is forward biased whereas collector base junction is reversed biased.
In the absence of the emitter base junction no current would flow in the collector circuit because of the reversed biased and if it is present forward biased on it possess the emitter current to flow.
Emitter current almost entirely flows in the collector circuit,therefore the current in the collector circuit depends upon the emitter current.
Figure shows the energy levels in an NPN transistor under no externally applying voltages.
In each of the N-type layers conduction can take place by the free movement of electrons in the conduction band.
In the P-type (filling) layer conduction can take place by the movement of the free holes in the valence band.
However, in the absence of any externally applied electric field, we find that depletion zones form at both PN-Junctions, so no charge wants to move from one layer to another.
NPN Bipolar Transistor
How the BJT works
What happens when we apply a moderate voltage between the collector and base parts.
The polarity of the applied voltage is chosen to increase the force pulling the N-type electrons and P-type holes apart.
This widens the depletion zone between the collector and base and so no current will flow.
In effect we have reverse-biassed the Base-Collector diode junction.
Apply a Collector-Base voltage
Charge FlowWhat happens when we apply a relatively small Emitter-Base voltage whose polarity is designed to forward-bias the Emitter-Base junction.
This 'pushes' electrons from the Emitter into the Base region and sets up a current flow across the Emitter-Base boundary.
Once the electrons have managed to get into the Base region they can respond to the attractive force from the positively-biassed Collector region.
As a result the electrons which get into the Base move swiftly towards the Collector and cross into the Collector region.
Hence a Emitter-Collector current magnitude is set by the chosen Emitter-Base voltage applied.
Hence an external current flowing in the circuit.
Apply an Emitter-Base voltage
Charge FlowSome of free electrons crossing the Base encounter a hole and 'drop into it'.
As a result, the Base region loses one of its positive charges (holes).
The Base potential would become more negative (because of the removal of the holes) until it was negative enough to repel any more electrons from crossing the Emitter-Base junction.
The current flow would then stop.
Some electron fall into a hole
Charge Flow To prevent this happening we use the applied E-B voltage to remove the captured electrons from the base and maintain the number of holes.
The effect, some of the electrons which enter the transistor via the Emitter emerging again from the Base rather than the Collector.
For most practical BJT only about 1% of the free electrons which try to cross Base region get caught in this way.
Hence a Base current, IB, which is typically around one hundred times smaller than the Emitter current, IE.
Some electron fall into a hole
Charge Flow To prevent this happening we use the applied E-B voltage to remove the captured electrons from the base and maintain the number of holes.
The effect, some of the electrons which enter the transistor via the Emitter emerging again from the Base rather than the Collector.
For most practical BJT only about 1% of the free electrons which try to cross Base region get caught in this way.
Hence a Base current, IB, which is typically around one hundred times smaller than the Emitter current, IE.
Some electron fall into a hole
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•Current flow in an npn transistor biased to operate in the active mode
•Forward bias of Emitter-Base Junction: current flows to emitter, electrons move towards base, holes to emitter
•Reverse bias of Base-Collector Junction: IC independent of VCB
NPN Transistor
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•Current in PNP mainly due to holes injected from emitter to base
PNP Transistor
Current carriers passing through an NPN transistor.
Current carriers passing through a PNP transistor.
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Qualitative discussion of transistor action
p pn
forwardI reverseI
No transistor action
e
Combine the two diodes!VF VR
h
45
Consider very thin base width: Transistor action
e
E
R
EIEI
E1 I)(
Hole concentration is zero here, reverse biased
VF VR
The collector current IC is almost equal to IE, and collector currentis controlled by the E-B junction bias. The loss, i.e. < 1 corresponds to the recombination of holes in base.
h
BJT Modes Cut-off Region: VBE < VFB, iB=0
Transistor acts like an off switch Active Linear Region: VBE=VFB, iB≠0, iC=βiB
Transistor acts like a current amplifier Saturation Region: VBE=VFB, iB>iC,max/ β
In this mode the transistor acts like an on switchPower across BJT
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47
iC-vCB characteristics for an npn transistor in the active mode.
•Collector is constant current source only controlled by emitter current iC
EC Ii
●BJT Characteristics
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Transistor as an amplifier. (b) The circuit of (a) with the signal source vbe eliminated for dc (bias) analysis.
TRANSISTOR SYMBOL
50
BJT circuit symbols
As shown, the currents are positive quantities when the transistor is operated in forward active mode.
IE = IB + IC and VEB + VBC + VCE = 0 VCE = VEC
51
Schematic representation of pnp and npn BJTs
Emitter is heavily doped compared to collector. So, emitterand collector are not interchangeable.
The base width is small compared to the minority carrierdiffusion length. If the base is much larger, then this willbehave like back-to-back diodes.
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