Bipolar Junction Transistor
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The document discusses the bipolar junction transistor (BJT). It describes how the BJT was invented in 1947 by scientists at Bell Labs. The BJT consists of three terminals - the emitter, base, and collector - and comes in two types, p-n-p and n-p-n. The document explains the basic operation and principles of both types of BJT, including how current flows when junctions are forward or reverse biased in different modes. It also provides examples of calculating currents given bias conditions and current gains. Finally, it summarizes the key current-voltage relationships and characteristics of BJTs in common base, common emitter, and common collector configurations.
![IE = IS [ e VBE / VT ]
Based on KCL: IE = IC + IB
IC = IB
IC = IE
= [ / + 1 ]
IE = IB( + 1)
IE = IS [ e VEB / VT]
NPN PNP
= [ / 1 - ]](https://image.slidesharecdn.com/bjt-170507172854/85/Bipolar-Junction-Transistor-12-320.jpg)
Bipolar Junction Transistor
- 1. BIPOLAR JUNCTION TRANSISTOR By Prankit Mishra FST, ICFAI University
- 2. INTRODUCTION A semiconductor triode is known as bipolar junction transistor (BJT) The transistor was invented by a team of three men at Bell Laboratories in 1947. Dr. William Shockley, Dr. John Bardeen, Dr. Walter H. Brattain. It can be used as amplifiers and logic switches The BJT consists three terminals: emitter (E), base (B), and collector(C)
- 3. Based on its construction, a junction transistor can be classified into two types: p-n-p transistor and n-p-n transistor A junction transistor consists of a silicon (or germanium) crystal in which a layer of n-type silicon is sandwiched between two layers of p-type silicon, called a p-n-p transistor. Alternatively, a transistor may consist of a layer of p-type between two layers of n-type material, called an n-p-n transistor The three layer of transistor are Emitter (E), Base (B) and Collector (C) shown in the figure The Emitter (E) layer is heavily doped; the base (B) and collector (C) layers are lightly doped.
- 5. BASIC OPERATION OF TRANSISTOR There are three mode of operations: If transistor is operating active mode, it can be used as amplifier. The transistor can be used as logical switch if it operates in cut-off and saturation mode. Bias Mode E-B Junction C-B Junction Saturation Forward Forward Active Forward Reverse Inverted active Reverse Forward Cutoff Reverse Reverse
- 6. OPERATING PRINCIPLES OF P-N-P TRANSISTOR Consider the active mode, that is E-B junction is forward biased and C-B junction is reverse biased (One p-n junction of a transistor is forward biased, while the other is reverse biased) shown in fig.
- 7. First take forward biased p-n junction ( E-B junction). The depletion region has been reduced in width due to the applied bias, resulting in a heavy flow of majority carriers (hole) from p-type to n-type. The emitter current IE consists two components: IpE (due to hole diffusion from E to B) and InE (due to electron diffusion from B to E) IE = IpE + InE Because the emitter is heavily doped than the base, the emitter current due to diffusion of holes from E to B. Therefore IE ≈ IpE The holes emitted from the emitter are injected into the n-type base region, some of these are recombine with the electrons in the base. It accounts for a small base current (IB) Most of them reach the C-B junction where they are instantaneously swept out by the strong electric field in the depletion layer of C-B junction
- 8. Then the holes are collected by the collector. The fraction ( ) of injected holes which are finally collected by the collector. is usually just less than 1 IC = IE Now consider the reverse biased p-n junction This reverse current (ICO) consists two components: one is InCO (due to the motion of electrons from p to n region across collector junction) and the other one is IpCO (due to motion of holes from n to p region across collector junction) The total collector current is where α is called large signal current gain. Typical range of α is 0.95 to 0.998 E COC COEC I II III
- 10. From Kirchhoff's Current law, IE = IC + IB Substituting this in IC ≈ IE we get IC = ( IC + IB ) or, IC = . IB 1 - or, IC = IB where, = / (1- ) = common emitter current gain. Also, = / ( 1+ ) If = 0.995, = 199 Usually is very close to unity and lies in the range of 25 – 350.
- 11. OPERATING PRINCIPLES OF N-P-N TRANSISTOR The operation of the npn transistor is exactly the same if the roles played by the electron and hole are interchanged
- 12. IE = IS [ e VBE / VT ] Based on KCL: IE = IC + IB IC = IB IC = IE = [ / + 1 ] IE = IB( + 1) IE = IS [ e VEB / VT] NPN PNP = [ / 1 - ]
- 13. EXAMPLE Calculate the collector and emitter currents, given the base current and current gain. Assume a common-base current gain and a base current of . Also assume that the transistor is biased forward in the forward active mode. Solution: The common-emitter current gain is The collector current is And the emitter current is
- 14. EXAMPLES EXAMPLE 1 Given IB = 6.0A and IC=510 A Determine , and IE EXAMPLE 2 NPN Transistor Reverse saturation current Is = 10-13A with current gain, = 90. Based on VBE = 0.685V, determine IC , IB and IE EXAMPLE 3 PNP Transistor = 60, IC= 0.85mA Determine , IE and IB
- 15. TRANSISTOR I-V CHARACTERISTICS Basically there are three types of circuit connections (called configurations) for operating transistor. Common base (CB) Common emitter (CE) Common collector CC) The term common is used to denote the electrode that is common to the input and output of the circuit
- 17. Summary of the BJT current‐voltage relationships in the active mode
- 18. TRANSISTORS CHARACTERISTICS ( COMMON BASE) Common Base Connection
- 19. Input characteristics of common base transistors
- 20. Typical output characteristics (CB) of an n-p-n transistors IC versus VCB plot with various IE as parameter is known as common‐base output characteristics
- 21. Common emitter circuit Input characteristics of an n-p-n transistors(CE)
- 22. Typical common emitter output characteristics of an n-p-n transistors