How does a transistor work?
A transistor is a fundamental semiconductor device that plays a pivotal role in modern electronics by acting as an amplifier and a switch. It operates based on the principles of semiconductor behavior and is typically composed of three layers: the emitter, base, and collector.
In a common type of transistor, the bipolar junction transistor (BJT), there are two types: NPN and PNP. When a small current flows from the base to the emitter in an NPN transistor (or from emitter to base in a PNP), it creates a larger current flow from the collector to the emitter (or emitter to collector) due to the configuration of the layers and their doping.
This small base current controls the much larger collector-emitter current, effectively amplifying the input signal. The transistor acts as an on-off switch when it’s operated in either its “cut-off” (no collector current) or “saturation” (full collector current) states.
The field-effect transistor (FET) is another major type, operating on the principle of electric fields. It has three terminals: source, gate, and drain. By applying a voltage to the gate, the electric field controls the flow of current between the source and the drain, making FETs efficient in high-frequency and low-power applications.
Transistors have revolutionized electronics, enabling compact and efficient circuit design, and serving as building blocks for various devices such as computers, amplifiers, and communication systems. Their ability to amplify and switch signals with great precision has driven the advancement of modern technology.