Characteristics and operation of SCS( Silicon Controlled Switch)

Operation of a Silicon Controlled Switch
The easiest way to understand how it operates is to realize it to be formed of two transistors Q₁ and Q₂ placed back-to-back, as shown in figure.b

In a two-transistor equivalent circuit shown in figure.c, it is seen that a negative pulse at the anode gate G₂ causes transistor Q₁ to switch on. Transistor Q₁ supplies base current to transistor Q₂, and both transistors switch-on. Similarly, a positive pulse at the cath­ode gate G₁ can switch the device on. Since only small currents are involved, the SCS may be switched off by an appropriate polarity pulse at one of the gates. At the cathode gate a negative pulse is required for switching-off while at the anode gate a positive pulse is needed.

Volt-Ampere Characteristic of SCS

The volt-ampere characteristic of an SCS is similar to that of an SCR and is shown in figure. With the increase in applied voltage, the current first increases slowly upto point A and then rapidly in the region AB, as shown in the figure. At point B, the product β₁β₂ exceeds unity and the device is suddenly switched on. In the on-state, the current increases enormously and is limited by the external series resistor. SCS also exhibits negative differential resistance in the on region similar to SCR. SCS gets switched on accidentally if the anode voltage gets applied suddenly. This is known as rate effect, which is caused by inter-electrode capacitance between elec­trodes G₁ and G₂, known as transition capacitance.

Advantages and Applications of SCS

An advantage of SCS over an SCR is the reduced turn-off time, typically within the range of 1 to 10 micro seconds for the SCS and 5 to 30 micro seconds for the SCR. Other advantages of the SCS over SCR are increased control and triggering sensitivity and a more predictable firing situation. However, the SCS is limited to low power, current, and voltage ratings (typical maximum anode currents range from 100 mA to 300 mA with dissipation rating of 100 to 500 mW).

A few of the more common areas of application of SCS include a variety of computer circuits (such as counters, registers, and timing circuits) voltage sensors, pulse generators, oscillators etc.

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