3.1 Differentiate between bistable multivibrators and astable multivibrators with reference to the output states - NSC Electrical Technology Electronics - Question 3 - 2023 - Paper 1

When S2 is pressed, the output will be in one of its stable states, which can either be high (+9V) or low (0V), depending on the previous state of the circuit.

Pressing S1 changes the configuration of the multivibrator. It changes the state from one stable point to another, effectively flipping the output voltage state from high to low or vice versa, based on the circuit's previous output level.

The output voltage will switch to the opposite state of what it was before S1 was pressed. If it was previously high (+9V), it will drop to low (0V), and if it was low, it will switch to high.

The output waveform would be a rectangular pulse that mirrors the input pulse characteristics, reflecting the changes in voltage across the specified time intervals.

This circuit uses an active low trigger to set the output, meaning that the output state changes when the trigger voltage falls below a certain threshold.

The threshold voltage of the circuit is the voltage level at which the output changes state. It can typically be calculated as half of the supply voltage, which would be 3V if using a 6V supply.

When the trigger is pressed and brought below the threshold voltage, the output changes state. For a monostable circuit, this will generate a single pulse of output for a specific duration determined by the RC time constant.

To eliminate unwanted noise, decoupling capacitors can be used at the supply pins of the circuit. Additionally, using a low-pass filter can help smooth out any high-frequency noise that can affect the timing.

The duty cycle is defined as the ratio of the time the output is high to the total time period of the waveform, expressed as a percentage. A 50% duty cycle means that the output is high for half of the time interval.

The charging time of the capacitor is typically longer than the discharging time due to the exponential nature of the charging curve in RC circuits, where the voltage approaches the supply voltage at a slower rate compared to the rapid discharge.

The voltage waveform across capacitor C1 will show a ramp-up during charging and a rapid fall during discharging, reflecting a triangular waveform shape during each cycle.