Hence, the pulse input supplied to base get amplified and received at capacitor C3. Here, the transistor work as an amplifier, we have used common-emitter configuration. Active region: when base voltage increases, but V BC (base to collector) voltage is still negative, upto this value, transistor remain in active region.Ī transistor will work as an amplifier only when it is operated in active region.Saturation region: When V BC and V BE increases and both get forward biased, then the transistor is in saturation region.Cut-off region: when voltage between base and emitter is less than 0.7V, transistor is in cut-off region.There are three operating regions of a transistor mentioned below: Here, R4 is used as current limiting resistor and C2 is used as bypass capacitor and R3-C3 are making a RC filter for the output signal. When supply is given to the circuit, the voltage divider circuit output provide enough voltage to bias the transistor. You can change the resistor value but the base input voltage should not exceed the range. A transistor’s base terminal voltage required to turn ON the transistor ranges from 0.7 (min) to 5V (max). Hence, the output of the voltage divider circuit is used for proper biasing to turn ON the transistor. In the above circuit diagram, we have made a voltage divider circuit using resistor R1 and R2 of 4.7k and 1.5k respectively. Simple Transistor Amplifier Circuit Diagram The output signal phase shift is 180⁰, hence the output and input are inverse to each other.Ĭomponents Required for a Transistor Amplifier Circuit This configuration is most used configuration among all the three, as it has average input and output impedance value. The current gain (Beta) is defined by the ratio of collector current and base current in this configuration. In this configuration, the sum of collector and base current is equal to the emitter current. Here, the input parameters are V BE and I B and output parameters are V CE and I C. This configuration is an inverting amplifier circuit. Input is supplied to the base terminal and the emitter is common for the Input and Output. In the CE (Common-Emitter) Configuration, we get output from the collector terminal. For, learning about other two configuration, types of transistors and their working follow the linked article. Here, we are explaining Common-Emitter configuration, as it is the most used and popular configuration. Common Emitter (CE) Configuration: It has current gain and voltage gain both.Common Collector (CC) Configuration: It has current gain but no voltage gain.Common Base (CB) Configuration: It has no current gain but has voltage gain.Generally, there are three types of configurations and their descriptions with respect to gain is as follows: For using a transistor as an amplifier we have three transistor configuration which are explained below. We have explained Transistor as a Switch in our previous tutorial, now for using a transistor as an amplifier we have demonstrated the circuit and it’s working in this tutorial. In this circuit we are using a NPN transistor for amplifying the signals which are demonstrated using an oscilloscope.Īs we know a transistor is generally used as a Transistor as a Switch or Transistor as an amplifier. There are two type of transistors: NPN Transistor and PNP Transistor. Emitter: Current drain out from this terminal, normally connected to ground.Collector: Current flow through this terminal. Base: This pin used for activating the transistor (minimum 0.7V required to turn ON a Transistor).They are highly durable, smaller in size and operates on a low voltage supply. Transistors are the semiconductor devices used for switching or amplifying electrical signals.
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