Bipolar Transistor

 Bipolar Transistor

The common emitter amplifier configuration produces the highest current and power gain of all the three bipolar transistor configurations. 

• Common Base Configuration   –   has Voltage Gain but no Current Gain.
• Common Emitter Configuration   –   has both Current and Voltage Gain.
• Common Collector Configuration   –   has Current Gain but no Voltage Gain.

The Bipolar Junction Transistor is a semiconductor device which can be used for switching or amplification

Unlike semiconductor diodes which are made up from two pieces of semiconductor material to form one simple pn-junction. The bipolar transistor uses one more layer of semiconductor material to produce a device with properties and characteristics of an amplfier.

If we join together two individual signal diodes back-to-back, this will give us two PN-junctions connected together in series which would share a common Positve, (P) or Negative, (N) terminal. The fusion of these two diodes produces a three layer, two junction, three terminal device forming the basis of a Bipolar Junction Transistor, or BJT for short.

Transistors are three terminal active devices made from different semiconductor materials that can act as either an insulator or a conductor by the application of a small signal voltage. The transistor’s ability to change between these two states enables it to have two basic functions: “switching” (digital electronics) or “amplification” (analogue electronics). Then bipolar transistors have the ability to operate within three different regions:

Active Region   –   the transistor operates as an amplifier and Ic = β*Ib
Saturation   –   the transistor is “Fully-ON” operating as a switch and Ic = I(saturation)
Cut-off   –   the transistor is “Fully-OFF” operating as a switch and Ic = 0

A Typical
Bipolar Transistor

The word Transistor is a combination of the two words Transfer Varistor which describes their mode of operation way back in their early days of electronics development. There are two basic types of bipolar transistor construction, PNP and NPN, which basically describes the physical arrangement of the P-type and N-type semiconductor materials from which they are made.

The Bipolar Transistor basic construction consists of two PN-junctions producing three connecting terminals with each terminal being given a name to identify it from the other two. These three terminals are known and labelled as the Emitter ( E ), the Base ( B ) and the Collector ( C ) respectively.
Bipolar Transistors are current regulating devices that control the amount of current flowing through them from the Emitter to the Collector terminals in proportion to the amount of biasing voltage applied to their base terminal, thus acting like a current-controlled switch. As a small current flowing into the base terminal controls a much larger collector current forming the basis of transistor action.
The principle of operation of the two transistor types PNP and NPN, is exactly the same the only difference being in their biasing and the polarity of the power supply for each type.

Bipolar Transistor Construction

The construction and circuit symbols for both the PNP and NPN bipolar transistor are given above with the arrow in the circuit symbol always showing the direction of “conventional current flow” between the base terminal and its emitter terminal. The direction of the arrow always points from the positive P-type region to the negative N-type region for both transistor types, exactly the same as for the standard diode symbol.

Bipolar Transistor Configurations

As the Bipolar Transistor is a three terminal device, there are basically three possible ways to connect it within an electronic circuit with one terminal being common to both the input and output signals. Each method of connection responding differently to its input signal within a circuit as the static characteristics of the transistor vary with each circuit arrangement.

• Common Base Configuration   –   has Voltage Gain but no Current Gain.
• Common Emitter Configuration   –   has both Current and Voltage Gain.
• Common Collector Configuration   –   has Current Gain but no Voltage Gain.

The Common Base (CB) Configuration

As its name suggests, in the Common Base or grounded base configuration, the BASE connection is common to both the input signal AND the output signal. The input signal is applied between the transistors base and the emitter terminals, while the corresponding output signal is taken from between the base and the collector terminals as shown. The base terminal is grounded or can be connected to some fixed reference voltage point.

The input current flowing into the emitter is quite large as its the sum of both the base current and collector current respectively therefore, the collector current output is less than the emitter current input resulting in a current gain for this type of circuit of “1” (unity) or less, in other words the common base configuration “attenuates” the input signal.

The Common Base Transistor Circuit

This type of amplifier configuration is a non-inverting voltage amplifier circuit, in that the signal voltages Vin and Vout are “in-phase”. This type of transistor arrangement is not very common due to its unusually high voltage gain characteristics. Its input characteristics represent that of a forward biased diode while the output characteristics represent that of an illuminated photo-diode. 

Also this type of bipolar transistor configuration has a high ratio of output to input resistance or more importantly “load” resistance ( RL ) to “input” resistance ( Rin ) giving it a value of “Resistance Gain”. Then the voltage gain ( Av ) for a common base configuration is therefore given as:

Common Base Voltage Gain

Where: Ic/Ie is the current gain, alpha ( α ) and RL/Rin is the resistance gain.

The common base circuit is generally only used in single stage amplifier circuits such as microphone pre-amplifier or radio frequency ( Rƒ ) amplifiers due to its very good high frequency response.

The Common Emitter (CE) Configuration

In the Common Emitter or grounded emitter configuration, the input signal is applied between the base and the emitter, while the output is taken from between the collector and the emitter as shown. This type of configuration is the most commonly used circuit for transistor based amplifiers and which represents the “normal” method of bipolar transistor connection.

The common emitter amplifier configuration produces the highest current and power gain of all the three bipolar transistor configurations. This is mainly because the input impedance is LOW as it is connected to a forward biased PN-junction, while the output impedance is HIGH as it is taken from a reverse biased PN-junction.

The Common Emitter Amplifier Circuit

In this type of configuration, the current flowing out of the transistor must be equal to the currents flowing into the transistor as the emitter current is given as Ie = Ic + Ib.

As the load resistance ( RL ) is connected in series with the collector, the current gain of the common emitter transistor configuration is quite large as it is the ratio of Ic/Ib. A transistors current gain is given the Greek symbol of Beta, ( β ).

As the emitter current for a common emitter configuration is defined as Ie = Ic + Ib, the ratio of Ic/Ie is called Alpha, given the Greek symbol of α. Note: that the value of Alpha will always be less than unity.

Since the electrical relationship between these three currents, Ib, Ic and Ie is determined by the physical construction of the transistor itself, any small change in the base current ( Ib ), will result in a much larger change in the collector current ( Ic ).

Then, small changes in current flowing in the base will thus control the current in the emitter-collector circuit. Typically, Beta has a value between 20 and 200 for most general purpose transistors. So if a transistor has a Beta value of say 100, then one electron will flow from the base terminal for every 100 electrons flowing between the emitter-collector terminal.

By combining the expressions for both Alpha, α and Beta, β the mathematical relationship between these parameters and therefore the current gain of the transistor can be given as:

Where: “Ic” is the current flowing into the collector terminal, “Ib” is the current flowing into the base terminal and “Ie” is the current flowing out of the emitter terminal.

Then to summarise a little. This type of bipolar transistor configuration has a greater input impedance, current and power gain than that of the common base configuration but its voltage gain is much lower. The common emitter configuration is an inverting amplifier circuit. This means that the resulting output signal has a 180o phase-shift with regards to the input voltage signal.

The Common Collector (CC) Configuration

In the Common Collector or grounded collector configuration, the collector is connected to ground through the supply, thus the collector terminal is common to both the input and the output. The input signal is connected directly to the base terminal, while the output signal is taken from across the emitter load resistor as shown. This type of configuration is commonly known as a Voltage Follower or Emitter Follower circuit.

The common collector, or emitter follower configuration is very useful for impedance matching applications because of its very high input impedance, in the region of hundreds of thousands of Ohms while having a relatively low output impedance.

The Common Collector Transistor Circuit

The common emitter configuration has a current gain approximately equal to the β value of the transistor itself. However in the common collector configuration, the load resistance is connected in series with the emitter terminal so its current is equal to that of the emitter current.

As the emitter current is the combination of the collector AND the base current combined, the load resistance in this type of transistor configuration also has both the collector current and the input current of the base flowing through it. Then the current gain of the circuit is given as:

The Common Collector Current Gain

This type of bipolar transistor configuration is a non-inverting circuit in that the signal voltages of Vin and Vout are “in-phase”. The common collector configuration has a voltage gain of about “1” (unity gain). Thus it can considered as a voltage-buffer since the voltage gain is unity.

The load resistance of the common collector transistor receives both the base and collector currents giving a large current gain (as with the common emitter configuration) therefore, providing good current amplification with very little voltage gain.

Having looked at the three different types of bipolar transistor configurations, we can now summarise the various relationships between the transistors individual DC currents flowing through each leg and its DC current gains given above in the following table.

Relationship between DC Currents and Gains

Note that although we have looked at NPN Bipolar Transistor configurations here, PNP transistors are just as valid to use in each configuration as the calculations will all be the same, as for the non-inverting of the amplified signal. The only difference will be in the voltage polarities and current directions.

Bipolar Transistor Summary

Then to summarise, the behaviour of the bipolar transistor in each one of the above circuit configurations is very different and produces different circuit characteristics with regards to input impedance, output impedance and gain whether this is voltage gain, current gain or power gain and this is summarised in the table below.

Bipolar Transistor Configurations

with the generalised characteristics of the different transistor configurations given in the following table:

Characteristic	Common Base	Common Emitter	Common Collector
Input Impedance	Low	Medium	High
Output Impedance	Very High	High	Low
Phase Shift	0o	180o	0o
Voltage Gain	High	Medium	Low
Current Gain	Low	Medium	High
Power Gain	Low	Very High	Medium

In the next tutorial about Bipolar Transistors, we will look at the NPN Transistor in more detail when used in the common emitter configuration as an amplifier as this is the most widely used configuration due to its flexibility and high gain. We will also plot the output characteristics curves commonly associated with amplifier circuits as a function of the collector current to the base current.

Transistor Tutorial Summary

 Transistor Tutorial Summary

We can summarise the main points in this transistors tutorial section as follows: 

Having looked at the construction and operation of NPN and PNP bipolar junctions transistors (BJT’s) as well as field effect transistors (FET’s), both junction and insulated gate, we can summarise the main points of these transistor tutorial as outlined below:

• The Bipolar Junction Transistor (BJT) is a three layer device constructed form two semiconductor diode junctions joined together, one forward biased and one reverse biased.
• There are two main types of bipolar junction transistors, (BJT) the NPN and the PNP transistor.
• Bipolar junction transistors are “Current Operated Devices” where a much smaller Base current causes a larger Emitter to Collector current, which themselves are nearly equal, to flow.
• The arrow in a transistor symbol represents conventional current flow.
• The most common transistor connection is the Common Emitter (CE) configuration but Common Base (CB) and Common Collector (CC) are also available.
• Requires a Biasing voltage for AC amplifier operation.
• The Base-Emitter junction is always forward biased whereas the Collector-Base junction is always reverse biased.
• The standard equation for currents flowing in a transistor is given as:  IE = IB + IC
• The Collector or output characteristics curves can be used to find either Ib, Ic or β to which a load line can be constructed to determine a suitable operating point, Q with variations in base current determining the operating range.
• A transistor can also be used as an electronic switch between its saturation and cut-off regions to control devices such as lamps, motors and solenoids etc.
• Inductive loads such as DC motors, relays and solenoids require a reverse biased “Flywheel” diode placed across the load. This helps prevent any induced back emf’s generated when the load is switched “OFF” from damaging the transistor.
• The NPN transistor requires the Base to be more positive than the Emitter while the PNP type requires that the Emitter is more positive than the Base.

Transistor Tutorial – The Field Effect Transistor

• Field Effect Transistors, or FET’s are “Voltage Operated Devices” and can be divided into two main types: Junction-gate devices called JFET’s and Insulated-gate devices called IGFET´s or more commonly known as MOSFETs.
• Insulated-gate devices can also be sub-divided into Enhancement types and Depletion types. All forms are available in both N-channel and P-channel versions.
• FET’s have very high input resistances so very little or no current (MOSFET types) flows into the input terminal making them ideal for use as electronic switches.
• The input impedance of the MOSFET is even higher than that of the JFET due to the insulating oxide layer and therefore static electricity can easily damage MOSFET devices so care needs to be taken when handling them.
• When no voltage is applied to the gate of an enhancement FET the transistor is in the “OFF” state similar to an “open switch”.
• The depletion FET is inherently conductive and in the “ON” state when no voltage is applied to the gate similar to a “closed switch”.
• FET’s have much higher current gains compared to bipolar junction transistors.
• The most common FET connection is the Common Source (CS) configuration but Common Gate (CG) and Common Drain (CD) configurations are also available.
• MOSFETS can be used as ideal switches due to their very high channel “OFF” resistance, low “ON” resistance.
• To turn the N-channel JFET transistor “OFF”, a negative voltage must be applied to the gate.
• To turn the P-channel JFET transistor “OFF”, a positive voltage must be applied to the gate.
• N-channel depletion MOSFETs are in the “OFF” state when a negative voltage is applied to the gate to create the depletion region.
• P-channel depletion MOSFETs, are in the “OFF” state when a positive voltage is applied to the gate to create the depletion region.
• N-channel enhancement MOSFETs are in the “ON” state when a “+ve” (positive) voltage is applied to the gate.
• P-channel enhancement MOSFETs are in the “ON” state when “-ve” (negative) voltage is applied to the gate.

The Field Effect Transistor Chart

Biasing of the Gate for both the junction field effect transistor, (JFET) and the metal oxide semiconductor field effect transistor, (MOSFET) configurations are given as:

Type	Junction FET		Metal Oxide Semiconductor FET
	Depletion Mode		Depletion Mode		Enhancement Mode
Bias	ON	OFF	ON	OFF	ON	OFF
N-channel	0V	-ve	0V	-ve	+ve	0V
P-channel	0V	+ve	0V	+ve	-ve	0V

Transistor Tutorial – Differences between a FET and a BJT

Field Effect Transistors can be used to replace normal Bipolar Junction Transistors in electronic circuits. A simple comparison in this transistor tutorial between FET’s and Transistors stating both their advantages and their disadvantages is given below.

	Field Effect Transistor (FET)	Bipolar Junction Transistor (BJT)
1	Low voltage gain	High voltage gain
2	High current gain	Low current gain
3	Very high input impedance	Low input impedance
4	High output impedance	Low output impedance
5	Low noise generation	Medium noise generation
6	Fast switching time	Medium switching time
7	Easily damaged by static	Robust
8	Some require an input to turn it “OFF”	Requires zero input to turn it “OFF”
9	Voltage controlled device	Current controlled device
10	Exhibits the properties of a Resistor
11	More expensive than bipolar	Cheap
12	Difficult to bias	Easy to bias

Below is a list of complementary bipolar transistors which can be used for the general–purpose switching of low-current relays, driving LED’s and lamps, and for amplifier and oscillator applications.

Complementary NPN and PNP Transistors

NPN	PNP	VCE	IC(max)	Pd
BC547	BC557	45v	100mA	600mW
BC447	BC448	80v	300mA	625mW
2N3904	2N3906	40v	200mA	625mW
2N2222	2N2907	30v	800mA	800mW
BC140	BC160	40v	1.0A	800mW
TIP29	TIP30	100v	1.0A	3W
BD137	BD138	60v	1.5A	1.25W
TIP3055	TIP2955	60v	15A	90W

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FET Current Source

Electronic Engineering NPN PNP Push Pull

Electronic Engineering

Electronic Components

Resistor
Capacitor (Ceramic, Electrolytic)
Diode
Transistor (NPN, PNP)
MOSFET (N-Channel, P-Channel
OP-AMPs
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Differential Voltage  ( + 15 / -15,  

Technical Knowledge
Ohm's law
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Push Pull - 

2 Emitter Follower 
No voltage but Current Gain

+ve
NPN ( +ve top half of wave) source PUSH current to the load, Vbe  
PNP (-ve botton half of wave) PULL the current from the load 
-ve

Middle Terminal is the Collector

Flow of Signal on A Push-Pull Amplifier using a NPN and PNP

+ ve ((90Volts)  - Class G amp - switch on when more than +45volts need )
mosfet N-Channel IRFOP9140N (Gate Drain Source)
NPN  C5240
+Ve (+45Volts)
Collector
Base  +0.6volts Bias (Needs +ve wave to turn on)
Emitter 
=> 0.22Ohm  => SPEAKER 
=> 0.22Ohm
PNP A1962
Emitter
Base -0.6 volts bias (Needs -ve wave to turn on)
Collector
-ve (-45Volts)
Mosfet P-Channel IRFP9150N (Gate Drain Source)
- ve (-90Volts)  - Class G amp - switch on when more than -45volts need )
                  
https://www.youtube.com/watch?v=JokusaT7eok&t=1534s
https://www.youtube.com/watch?v=S7jrirsfkNw&t=20s


How to identify PNP or NPN Transistors

Emitter, Base, Collector

P  (Positive)
N  (Negative)
P  Positive 


BC547                        BC157

N  P  N                       P  N  P

you'll have 0.7 ohm reading with NP or PN junction is Good  and no reading if terminal leads change.
Base  +                       Base  -
Emitter  -                    Emitter  +
Collector -                   Collector +

NPN  - Red Led on Base and Black led on Emitter or Collector you will have .6 ohms
     - Black Led on Base and Red led on Emitter or Collector you will have No Reading 

PNP  - Black Led on Base and Red led on Emitter or Collector you will have .6 ohms
     - Red Led on Base and Black led on Emitter or Collector you will have Mo Reading



Meter in Diode Mode
Red Led  (Voltage/Ohm)
Black Led  (Common)

meter reads  O.L is Over Limit. eg . So if you are on a 2 V voltage range and try to measure 3 V, it will show OL.

(Note: Arrow defines the emitter and conventional current flow, “in” for a PNP transistor.)

Identifying the PNP Transistor

We saw in the first tutorial of this transistors section, that transistors are basically made up of two Diodes connected together back-to-back.

We can use this analogy to determine whether a transistor is of the PNP type or NPN type by testing its Resistance between the three different leads, Emitter, Base and Collector. By testing each pair of transistor leads in both directions with a multimeter will result in six tests in total with the expected resistance values in Ohm’s given below.

1. Emitter-Base  – The Emitter to Base should act like a normal diode and conduct one way only.

2. Collector-Base – Collector-Base junction should act like a normal diode & conduct one way only.

3. Emitter-Collector – The Emitter-Collector should not conduct in either direction.

Then we can define a PNP Transistor as being normally “OFF” but a small output current and negative voltage at its Base ( B ) relative to its Emitter ( E ) will turn it “ON” allowing a much large Emitter-Collector current to flow. PNP transistors conduct when Ve is much greater than Vc. 

In other words, a Bipolar PNP Transistor will ONLY conduct if both the Base and Collector terminals are negative with respect to the Emitter

In the next tutorial about Bipolar Transistors instead of using the transistor as an amplifying device, we will look at the operation of the transistor in its saturation and cut-off regions when used as a solid-state switch. 

Bipolar transistor switches are used in many applications to switch a DC current “ON” or “OFF”, from LED’s which require only a few milliamps of switching current at low DC voltages, or motors and relays which may require higher currents at higher voltages.

visual inspection of board
- Look for burn components
- Loose connections
- Capacitors bulging
- Missing components
- Cold solder joints 
- Cracked solder joints







5/8" Plywood Front Panel



Empty 15 Inch Speaker Cabinet with Titanium Horns

MODEL:SA-15T_Empty
CONTENTS:Empty 15 Inch PA/DJ Speaker Cabinet
CONDITION: New
APPLICATION: PA Speaker | Main | PA Loudspeaker | Live Sound
ACTIVE/PASSIVE: Passive

TWEETER/HORN: 1.5" Titanium Tweeter Driver with 10 oz Magnet and 1" Throat

CROSSOVER FREQUENCY: 12/18 dB per octave, 3 kHz High Power with Dual glass bulb tweeter protection

CONNECTORS:Two 1/4" and Two Speakon

NOMINAL IMPEDANCE: 8 Ohms

GRILL: Full Metal Grill
HANDLES: Recessed Plastic

ENCLOSURE: 5/8" Plywood Front Panel
POLE MOUNT: Yes
CABINET CUTOUT DIMENSIONS: 13 7/8"
HEIGHT: 29"
WIDTH: 18"
DEPTH:15"
WEIGHT: 34.7 lbs per Cabinet


incoherent, bad memory,  

Reference 

https://www.electronics-tutorials.ws/transistor/tran_3.html

Mixer => AMP Cables

 

For cables, it depends on what out you go out of the MIXER. 

Mixer - MAIN =>XLR to 1/4" cables =>  AMP 

Mixer - CTRL RM Outs => 1/4" to 1/4" cables => AMP

Full Range - 1st & 2nd Order High Pass & Low Pass Filter Band Pass

 Full Range   = All frequency signal to Speaker

First Order High Pass Filter

• One Capacitor = First Order High Pass Filter
• Capacitor in series to speaker = high frequency only plays on speaker 
• Hight pass crossover are usef to blocking base to small speaker or revent base and midrange from reaching twitter 
• At low freuency it shutoff (open circuit) because of capacitor plates and dielectrict)
• 4.7uf 600v (6db/octave) cap in series of speaker(twitter)

Second Order High Pass Filter

• One Capacitor + One Coil = Second Order High Pass Filter
• capacitor in series follow by parllel coil (across speaker terminals)
• (12db/octave)
• capacitor in series follow by parllel coil (across speaker terminals)
• (6db/octave)

First Order LOW Pass Filter

• One coil = First Order LOW Pass Filter
• First Order (6db/octive) low pass filter 
• Coil in Series to speaker 

Low pass crossover are used to provide pure bass to subwoofer and only bass and midrange 

to mid woofers in 2-way or 3-way systems  (passed signals and as frequency increases it goes to zero)

Second Order Low Pass Filter

• One Coil + One Capacitor = Second Order Low Pass Filter
• Coil in series follow by parllel capacitor (across speaker terminals)
• (12db/octave)

BAND Pass

• capacitor in series with Coil to speaker
• Fird order (6db/octive) bandpass filter
• capacotr in series follow by a coil in series 
• no base, no tribble, only mid-range
• Band pass crossover are less commmon by often used in 2 ay system for midrance 
• it passes certern band (range of sound)