Transistor – Overview After knowing the details about a single PN junction, or simply a diode, let us try to go for the two PN junction connection. If another P-type material or N-type material is added to a single PN junction, another junction will be formed. Such a formation is simply called as a Transistor. A Transistor is a three terminal semiconductor device that regulates current or voltage flow and acts as a switch or gate for signals. Uses of a transistor A transistor acts as an Amplifier, where the signal strength has to be increased. A transistor also acts as a switch to choose between available options. It also regulates the incoming current and voltage of the signals. Constructional Details of a Transistor The Transistor is a three terminal solid state device which is formed by connecting two diodes back to back. Hence it has got two PN junctions. Three terminals are drawn out of the three semiconductor materials present in it. This type of connection offers two types of transistors. They are PNP and NPN which means an N-type material between two Ptypes and the other is a P-type material between two N-types respectively. The following illustration shows the basic construction of transistors The three terminals drawn from the transistor indicate Emitter, Base and Collector terminals. They have their functionality as discussed below. Emitter The left-hand side of the above shown structure can be understood as Emitter. This has a moderate size and is heavily doped as its main function is to supply a number of majority carriers, i.e. either electrons or holes. As this emits electrons, it is called as an Emitter. This is simply indicated with the letter E. Base The middle material in the above figure is the Base. This is thin and lightly doped. Its main function is to pass the majority carriers from the emitter to the collector. This is indicated by the letter B. Collector The right side material in the above figure can be understood as a Collector. Its name implies its function of collecting the carriers. This is a bit larger in size than emitter and base. It is moderately doped. This is indicated by the letter C. The symbols of PNP and NPN transistors are as shown below. The arrow-head in the above figures indicated the emitter of a transistor. As the collector of a transistor has to dissipate much greater power, it is made large. Due to the specific functions of emitter and collector, they are not interchangeable. Hence the terminals are always to be kept in mind while using a transistor. In a Practical transistor, there is a notch present near the emitter lead for identification. The PNP and NPN transistors can be differentiated using a Multimeter. The following image shows how different practical transistors look like. We have so far discussed the constructional details of a transistor, but to understand the operation of a transistor, first we need to know about the biasing. Transistor Biasing As we know that a transistor is a combination of two diodes, we have two junctions here. As one junction is between the emitter and base, that is called as Emitter-Base junction and likewise, the other is Collector-Base junction. Biasing is controlling the operation of the circuit by providing power supply. The function of both the PN junctions is controlled by providing bias to the circuit through some dc supply. The figure below shows how a transistor is biased. By having a look at the above figure, it is understood that The N-type material is provided negative supply and P-type material is given positive supply to make the circuit Forward bias. The N-type material is provided positive supply and P-type material is given negative supply to make the circuit Reverse bias. By applying the power, the emitter base junction is always forward biased as the emitter resistance is very small. The collector base junction is reverse biased and its resistance is a bit higher. A small forward bias is sufficient at the emitter junction whereas a high reverse bias has to be applied at the collector junction. The direction of current indicated in the circuits above, also called as the Conventional Current, is the movement of hole current which is opposite to the electron current. Operation of PNP Transistor The operation of a PNP transistor can be explained by having a look at the following figure, in which emitter-base junction is forward biased and collector-base junction is reverse biased. The voltage VEE provides a positive potential at the emitter which repels the holes in the P-type material and these holes cross the emitter-base junction, to reach the base region. There a very low percent of holes re-combine with free electrons of N-region. This provides very low current which constitutes the base current IB. The remaining holes cross the collector-base junction, to constitute collector current IC, which is the hole current. As a hole reaches the collector terminal, an electron from the battery negative terminal fills the space in the collector. This flow slowly increases and the electron minority current flows through the emitter, where each electron entering the positive terminal of VEE, is replaced by a hole by moving towards the emitter junction. This constitutes emitter current IE. Hence we can understand that − The conduction in a PNP transistor takes place through holes. The collector current is slightly less than the emitter current. The increase or decrease in the emitter current affects the collector current. Operation of NPN Transistor The operation of an NPN transistor can be explained by having a look at the following figure, in which emitter-base junction is forward biased and collector-base junction is reverse biased. The voltage VEE provides a negative potential at the emitter which repels the electrons in the N-type material and these electrons cross the emitter-base junction, to reach the base region. There, a very low percent of electrons re-combine with free holes of P-region. This provides very low current which constitutes