Transistor as a switch
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Transistors can be used as switches by operating them in either saturation or cut-off regions. In saturation, the transistor is fully on with maximum collector current and minimum voltage drop. In cut-off, it is fully off with zero collector current and maximum voltage. Transistor switches allow interfacing low voltage digital logic to devices requiring higher voltages and currents, and can be used to control lamps, relays, motors and other loads. The base resistor value must be calculated to fully turn the transistor on above a given input voltage.
Transistor as a switch
- 1. Transistor as a switch 1 Eelectronic Devices and Circuit Active Learning Assignment
- 2. What is transistor? • When an n-type or p- type semiconductor is Connect between two p-type or n-type semiconductor respectively then two PN junction formed. Such a two junction device is called as TRANSISTOR • Thus transistor is a two junction , three layered, three terminal semiconductor device. • The transistor made by Silicon , Germanium material. • Transistor has mainly two type. 1) PNP Transistor 2) NPN Transistor
- 3. Transistor as a Switch • When used as an AC signal amplifier, the transistors Base biasing voltage is applied in such a way that it always operates within its “active” region, that is the linear part of the output characteristics curves are used. However, both the NPN & PNP type bipolar transistors can be made to operate as “ON/OFF” type solid state switches by biasing the transistors base differently to that of a signal amplifier. • Transistor switch operating region • NPN Transistor and PNP Transistor V-I Characteristics curves have seen in figure.
- 4. • The areas of operation for a Transistor Switch are known as the Saturation Region and the Cut-off Region. This means then that we can ignore the operating Q-point biasing and voltage divider circuitry required for amplification, and use the transistor as a switch by driving it back and forth between its “fully-OFF” (cut-off) and “fully-ON” (saturation) regions as shown in figure. • The pink shaded area at the bottom of the curves represents the “Cut-off” region while the blue area to the left represents the “Saturation” region of the transistor. Both these transistor regions are defined as: 1. Cut-off Region • Then we can define the “cut-off region” or “OFF mode” when using a bipolar transistor as a switch as being, both junctions reverse biased, VB < 0.7v and IC = 0. For a PNP transistor, the Emitter potential must be negative with respect to the Base.
- 5. • Here the operating conditions of the transistor are zero input base current ( IB ), zero output collector current ( IC ) and maximum collector voltage ( VCE ) which results in a large depletion layer and no current flowing through the device. Therefore the transistor is switched “Fully- OFF”. • transistor switch in cut-off
- 6. 2. Saturation Region • Here the transistor will be biased so that the maximum amount of base current is applied, resulting in maximum collector current resulting in the minimum collector emitter voltage drop which results in the depletion layer being as small as possible and maximum current flowing through the transistor. Therefore the transistor is switched “Fully-ON”. • Saturation Characteristics • transistor switch in saturation
- 7. • Then we can define the “saturation region” or “ON mode” when using a bipolar transistor as a switch as being, both junctions forward biased, VB > 0.7v and IC = Maximum. For a PNP transistor, the Emitter potential must be positive with respect to the Base. Digital Logic Transistor Switch • Transistor switches are used for a wide variety of applications such as interfacing large current or high voltage devices like motors, relays or lamps to low voltage digital logic IC’s or gates like AND gates or OR gates. Here, the output from a digital logic gate is only +5v but the device to be controlled may require a 12 or even 24 volts supply. Or the load such as a DC Motor may need to have its speed controlled using a series of pulses (Pulse Width Modulation). transistor switches will allow us to do this faster and more easily than with conventional mechanical switches.
- 8. Digital Logic Transistor Switch
- 9. A Switch Example Using the transistor values from the previous tutorials of: β = 200, Ic = 4mA and Ib = 20uA, find the value of the Base resistor (Rb) required to switch the load fully “ON” when the input terminal voltage exceeds 2.5v. • Transistor Switch Base Resistance
- 10. Application • Transistor switches can be used to switch and control lamps, relays or even motors. • When using the bipolar transistor as a switch they must be either “fully- OFF” or “fully-ON”. • Transistors that are fully “ON” are said to be in their Saturation region. • Transistors that are fully “OFF” are said to be in their Cut-off region. • When using the transistor as a switch, a small Base current controls a much larger Collector load current • When using transistors to switch inductive loads such as relays and solenoids, a “Flywheel Diode” is used. • When large currents or voltages need to be controlled, Darlington Transistors can be used
- 11. Thank you