1. To Design and Implement Monostable Multivibrator Circuit Using IC555
LAB:- CEII (SEM V EXTC)

2. AIM
To Design and Study the operation of monostable multivibrator using IC555 Timer
LAB:- CEII (SEM V EXTC)

3. Apparatus 555 Timer IC Resistor ( Values as per design)
Capacitors (Values as per Design)
Function Generator
CRO
Bread Board
Connecting Wires and Probes
LAB:- CEII (SEM V EXTC)

4. Functional Block Diagram of IC555:-
Theory
Functional Block Diagram of IC555:-
Reference:-
LAB:- CEII (SEM V EXTC)

5. Functional Block Diagram of IC555:-
Timer IC consists of two comparators
A resistive voltage divider generating the required reference voltage for the two comparator
SR flip-flop
Output Buffer
Discharging Transistor T1
LAB:- CEII (SEM V EXTC)

6. Multivibrators
It is a circuit which can have no, one or two stable states of operation.
Types :-
Astable Multivibrator:- No stable state
Monostable Multivibrator:- One stable state
Bistable Multivibrator :- Two stable states
LAB:- CEII (SEM V EXTC)

7. Monostable Multivibrator using IC555
Fig 1. :Monostable Multivibrator using IC555
Reference:-
LAB:- CEII (SEM V EXTC)

8. Monostable Multivibrator
The monostable multivibrator is also called as one shot, as it generates a single pulse of desired duration after getting a trigger signal.
The time constant of the externally connected resistor-capacitor
to IC 555 determines the length of the pulse.
LAB:- CEII (SEM V EXTC)

9. Monostable Multivibrator
The Monostable Multivibrator will be in its stable state (Output LOW) until it is triggered. 
When a negative trigger is applied to the trigger pin of 555 Timer, output of lower comparator will become HIGH and output of upper comparator will be LOW, since the capacitor voltage is zero. This makes the output HIGH.
The Discharge transistor turns OFF and the capacitor starts charges through resistor R to Vcc.
After the negative trigger, output of lower comparator becomes LOW and that of upper comparator remains LOW. Since both inputs of the SR Flip Flop are LOW, output will not change, so the output is HIGH.
LAB:- CEII (SEM V EXTC)

10. Waveform Monostable
Reference :-
LAB:- CEII (SEM V EXTC)

11. Design Equations Vc = Vcc[ 1-e-t/RC] t= on time
1. The charging equations of capacitor is given by:-
Vc = Vcc[ 1-e-t/RC]
Where, Vc= capacitor voltage
t= on time
2. During on time duration of output pulse capacitor voltage reaches a level of 2/3Vcc
Hence /3 Vcc= Vcc[ 1-e-Ton/RC]
Ton = 1.1 RC
Where , R = Externally connected resistor
C = Externally connected capacitor
LAB:- CEII (SEM V EXTC)

12. Design Statement for Implementation
Design a monostable multivibrator using IC555 for Vcc= 12V and pulse width of 1.65msec. Soln:- Pulse width = Ton= 1.1 R C Hence, 1 msec = 1.1 RC Let C= 0.1 uF 1.65*10-3 = 1.1 R * 0.1 * 10-6 R= 15 KὨ
LAB:- CEII (SEM V EXTC)

13. Procedure
1. Mount the circuit as per design on bread board. 2. Apply negative triggering pulse of 1 KHz at pin 2 and Vcc= 5V 3. Observe the output and capacitor voltage waveforms on CRO. 4. Compare the obtained results with designed values.
LAB:- CEII (SEM V EXTC)

14. Observation
Map out the time period of the output wave form and compare it with the given one.
Parameter
Designed
Observed
Ton
LAB:- CEII (SEM V EXTC)

15. Results and Discussion
The waveform is observed and verified with required condition.
LAB:- CEII (SEM V EXTC)

16. Questions What is the working principle of Monostable Multivibrator?
Why the name is given as monostable?
LAB:- CEII (SEM V EXTC)