5.1 Name the type of multivibrator that: 5.1.1 Produces one pulse cycle of 'high' and 'low' when a trigger pulse is applied to its input - NSC Electrical Technology Electronics - Question 5 - 2022 - Paper 1

The type of multivibrator that changes state when a trigger pulse is applied and remains in that state is a Bistable Multivibrator.

The function of resistor R1 is to keep the voltage on pin 4 high, which ensures that the 555 timer is active and ready to receive trigger pulses.

The function of resistor R3 is to limit the current flowing to the LED, protecting it from excessive current that could burn it out.

When trigger pin 2 is high, the state of the LED is OFF.

When the set switch is pressed, it pulls pin 2 'low' (0 V), causing the output to go 'high'. This activates the LED by providing sufficient voltage across it.

Connecting pin 6 to ground ensures the 555 timer can reset properly by providing a reference point for the threshold voltage, allowing the circuit to function as intended.

The purpose of resistor R2 is to set the reference voltage on the inverting input of the op-amp comparator.

As the level of light increases, the resistance of the LDR decreases, which increases the voltage on the non-inverting input of the op-amp.

The op-amp compares the voltages on its two input terminals. If the voltage on the non-inverting input is higher than that on the inverting input, the output drives to the positive saturation level. Conversely, if the inverting input is higher, the output goes to the negative saturation level.

When the voltage on the non-inverting terminal is higher, LED1 will be ON (illuminated), while LED2 will be OFF.

The type of Schmitt trigger circuit is an Inverting Schmitt Trigger.

When the voltage on the non-inverting input is -1 V, the output voltage will be -10 V.

This circuit uses positive feedback to create hysteresis, which helps in stabilizing the output.

The circuit operates by comparing the input voltage to two trigger voltage levels, the upper and lower thresholds. When the input exceeds the upper threshold, the output goes high, and when it falls below the lower threshold, the output goes low, creating a stable ON/OFF state.

An increase in R1 will cause the trigger voltage levels to increase, shifting the points at which the output changes state.

The variable resistor Rf serves to control the gain of the amplifier and also allows for adjustable feedback in the circuit.

The output voltage can be calculated using the voltage divider formula:

$V_{out} = \frac{V_{in} R_f}{R_f + R_{2} + R_{3}}$ Given the values, we find: $V_{out} = \frac{(0.4)(78,260) + (0.5)(78,260) + (0.25)(78,260)}{100,000} = 9 V$

An increase in the value of Rf will increase the gain of the amplifier, making it more sensitive to input signals. However, this may also lead to distortion if the output exceeds the supply limits.

Increasing Rf beyond 78,26 kΩ is not recommended because it could push the amplifier into saturation and cause clipping of the output signal, leading to a loss of signal integrity.

This limitation can be overcome by adjusting the supply voltage to the op-amp so that it can handle larger outputs without clipping, or by using feedback to stabilize the output.

The output waveform will represent the charging behavior of the capacitor, showing a more gradual rise and fall time as compared to the original value.

The output waveform will be even more gradual in charging and discharging, indicating a slower response time due to the larger capacitance.