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Astable Multivibrator

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1 Astable Multivibrator

2 Introduction An astable multivibrator, often called a free-running multivibrator, is a rectan­gular-wave generating cir­cuit. Unlike the monostable multivibrator, this circuit does not require any ex­ternal trigger to change the state of the output, hence the name free-running. An astable multivibrator can be produced by adding resistors and a capacitor to the basic timer IC, as illustrated in figure. The timing during which the output is either high or low is determined by the externally connected two resistors and a capacitor. The details of the astable multivibrator circuit are given below.

3

4 Cont..., Pin 1 is grounded; pins 4 and 8 are shorted and then tied to supply +Vcc, output (VOUT is taken form pin 3; pin 2 and 6 are shorted and the connected to ground through capacitor C, pin 7 is connected to supply + VCC through a resistor RA; and between pin 6 and 7 a resistor RB is connected. At pin 5 either a bypass capacitor of 0.01 F is connected or modulation input is applied.

5 Astable Multivibrator & Waveforms

6 2) Astable Multivibrator(Oscillator)
UCC + C1 C2 Q RD SD . 5K VA VB T 1 3 2 4 5 6 7 8 (grand) uO charge . uC R1 R2 + 1 1 1 >2/3 UCC <1/3 UCC first uC=0 1 RD=1 SD=0 discharge

7 . uC uO uO 4 8 5 6 2 7 1 3 uC tp1 tp2 t tp1 tp2 With one stable state
+VCC uO . uC C R1 R2 tp1 tp2 2/3UCC 1/3UCC uC t uO tp1 =(R1+R2)C ln2=0.7(R1+R2)C tp2 =R2C ln2=0.7R2C T=tp1+tp2 =0.7(R1+2R2)C Duty Cycle = tp1/T With one stable state

8 Astable Multivibrator Operation

9 In figure, when Q is low or output VOUT is high, the discharging transistor is cut-­off and the capacitor C begins charging toward VCC through resistances RA and RB. Because of this, the charging time constant is (RA + RB) C. Eventually, the threshold voltage exceeds +2/3 VCC, the comparator 1 has a high output and triggers the flip-flop so that its Q is high and the timer output is low. With Q high, the discharge transistor saturates and pin 7 grounds so that the capacitor C discharges through resistance RB with a discharging time constant RB C. With the discharging of capacitor, trigger voltage at inverting input of comparator 2 decreases. When it drops below 1/3VCC, the output of comparator 2 goes high and this reset the flip-flop so that Q is low and the timer output is high. This proves the auto-transition in output from low to high and then to low as. Thus the cycle repeats.

10 555 Timer Astable Multivibrator Circuit

11 Cont.., This circuit diagram shows how a 555 timer IC is configured to function as an astable multivibrator. An astable multivibrator is a timing circuit whose 'low' and 'high' states are both unstable. As such, the output of an astable multivibrator toggles between 'low' and 'high' continuously, in effect generating a train of pulses. This circuit is therefore also known as a 'pulse generator' circuit.

12 Cont.., In this circuit, capacitor C1 charges through R1 and R2, eventually building up enough voltage to trigger an internal comparator to toggle the output flip-flop. Once toggled, the flip-flop discharges C1 through R2 into pin 7, which is the discharge pin. When C1's voltage becomes low enough, another internal comparator is triggered to toggle the output flip-flop. This once again allows C1 to charge up through R1 and R2 and the cycle starts all over again. C1's charge-up time t1 is given by: t1 = 0.693(R1+R2)C1. C1's discharge time t2 is given by: t2 = 0.693(R2)C1. Thus, the total period of one cycle is t1+t2 = C1(R1+2R2). The frequency f of the output wave is the reciprocal of this period, and is therefore given by: f = 1.44/(C1(R1+2R2)), wherein f is in Hz if R1 and R2 are in mega ohms and C1 is in microfarads.

13 Behavior of the Astable Multivibrator
The astable multivibrator is simply an oscillator. The astable multivibrator generates a continuous stream of rectangular off-on pulses that switch between two voltage levels. The frequency of the pulses and their duty cycle are dependent upon the RC network values. The capacitor C charges through the series resistors R1 and R2 with a time constant (R1 + R2)C. The capacitor discharges through R2 with a time constant of R2C

14 Uses of the Astable Multivibrator
Flashing LED’s Pulse Width Modulation Pulse Position Modulation Periodic Timers (see mushroom timer in the experiment).

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