  Radio and Electronics (DED Philippinen, 66 p.)  11. ACTIVE COMPONENTS -2- / TRANSISTORS  11.2. CHARACTERISTICS OF TRANSISTORS  (introduction...) 11.2.1 HANDLING OF CHARACTERISTICS OF TRANSISTORS

### (introduction...)

If a technician wants to use transistor in a certain electronic device, he has to know first exactly how it will work under the conditions given in this very circuit. To make it possible to predict the function of such a transistor, the producers of transistors supply the users with so called “data sheets”.

Beside a lot of values given directly in those data sheets, they are also plotting the most important characteristics of the transistors.

FIELD OF CHARACTERISTICS

If we consider for a moment again our transistor we find our easily that there are four electrical factors on which it is depending on.

 - the base-emitter voltage VBE - the base-current IB - the collector-emitter voltage VCE, and - the collector-current IC

To make the relations between those factors more obvious, we find nowadays very often the so called

Fig. 130 shows a plot of such a kind. fig. 130

QUADRANT 3 - shows the relation between the base-current and the base-emitter voltage. This is always a graph very similar as the graph of a diode, only turned around, so that it fits into this part of the field. So the base and the emitter are connected to the input of the common-emitter-connection, the characteristics is called the INPUT-CHARACTERISTICS.

This term can be understood too if you think about the explanation of the function of a transistor, where the base current was described as the precondition for the collector current.

QUADRANT 1 - shows the relation of the collector-current and the collector-emitter-voltage. We can see it also as the representation of the resistance between collector and emitter. So this resistance is depending on the base current, there are different graphs, for different amounts of base-current. Because the collector and the emitter are connected to the output side of a common-emitter connection, the characterics shown in this quadrant are called OUTPUT-CHARACTERISTICS.

QUADRANT 2 - represents the relation between the collector-current and the base-current. This means, it shows the relation between one factor which is part of the input side of the circuit and another which is part of the output side. Therefore this graph is called the MUTUAL-CHARACTERISTICS.

QUADRANT 4 - is used very rarely and only its name shall be only mentioned here: FEEDBACK CHARACTERISTICS-

### 11.2.1.1. CONSTRUCTION OF THE STATIC-MUTUAL-CHARACTERISTICS

Even if you find in a given four-quadrant-characteristics a so called mutual-characteristics this is very often not fitting, because this characteristics is changing when collecter-emitter-voltage is changing. For this reason it is necessary to know how this characteristics can be found for each voltage you want it. fig. 131a

A) draw a vertical line into the 1. quadrant at the collector-emitter-voltage for which you want the mutual-characteristics. fig. 131b

B) draw horizontal lines through the points at which this vertical line is crossed over by the lines of the output-characteristics. fig. 131c

C) Find out the values of the base current represented by the crossed over lines in the output-characteristics and mark the horizontal lines at those values of the base-current in the 2. quadrant. fig. 131d

D) Connect all the points which you have found to get a new graph - this is the mutual characteristics for the desired collector-emitter-voltage. fig. 131e

### 11.2.1.2. CONSTRUCTION OF THE DYNAMIC MUTUAL CHARACTERISTICS

If the transistor is connected in a circuit the mutual characteristics changes according to the parameters given in this very circuit. The graph, showing this characteristics, is called the DYNAMIC MUTUAL CHARACTERISTICS and it shows actually the ability of amplifications of this very circuit.

To construct it, we enter the loadline of the collector-resistor into the output quadrant and find the values of the collector-current for each given base-current. The relation Ic/Ib is represented then in the 2. quadrant as shown in fig. 133. fig. 133

For the given circuit of a transistor with the given characteristics, an Rc of 300 Ohms and a supply voltage of 9 Volts, we find that the amplification is rather constant as long as the base-current does not exceed 3 mA. Above this value the amplification is decreased down to 0.

Mind too, that the output voltage Vce is high at low base-currents (low-input-signal) and vice versa.

### 11.2.1.3. CONSTRUCTION OF THE MAXIMUM-POWER-LINE

Each transistor has a maximum power rating. Which means: this is the power which can be dissipated by it, without danger of destruction.

Therefore it is extremly important to make sure that the transistor is always operated on “the safe side” - which means in our field of characteristics: on the safe side of the maximum power line. For this reason it is necessary to be able to construct the maximum-power-line. fig. 132

A) find in the data sheets the maximum permissible power for the transistor.

B) Calculate for various collector-emitter-voltages the permissible collector-current for this power. (The power dissipated for the input-values is so minute, that it can be neglected).

Ic = Ptot / Vce

C) Construct the Power-line by inserting the values of Ic for the different collector-emitter voltages.

The maximum powerline represents the field of application in a safe-area and a not allowed area. fig. 132a