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IDEAL OPERATIONAL AMPLIFIER AND OP-AMP CIRCUITS

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Presentation on theme: "IDEAL OPERATIONAL AMPLIFIER AND OP-AMP CIRCUITS"— Presentation transcript:

1 IDEAL OPERATIONAL AMPLIFIER AND OP-AMP CIRCUITS
CHAPTER 8 IDEAL OPERATIONAL AMPLIFIER AND OP-AMP CIRCUITS

2 Open loop mode Vo = Aod ( v2 – v1)
inverting non-inverting output Op-amp circuit symbol Open loop mode Vo = Aod ( v2 – v1) Aod is referred to as the open loop gain. Notice that is v2 = v1, the open loop gain equals to 

3 Final Exam SEM II 2012/2013 An ideal op-amp, was measured in a lab experiment in open-loop mode. Determine the open loop gain (Aod) and complete the table below which shows the results of the experiment. V1 (1) V2 (2) Vo (3) -1mV +1mV 1V -0.5V -3V 5V V 0.99 V

4 Op amp can be configured to be used for different type of circuit applications:
Inverting Amplifier Non – inverting Amplifier Summing Amplifier Integrator Differentiator

5 Two main characteristics:
We want the open loop gain to be equal to  which means that v2 = v1 We also want the input resistance to be equal to  , hence there is no current going into the op-amp

6 Inverting Amplifier Op-amp as an inverting amplifier
Voltage at node 1 (inverting) = voltage at node 2 (non-inverting ) KCL at node 1: (Vi – 0) / R1 = (0 – Vo) / R2 Vi / R1 = - Vo / R2 Vo = - R2 Vi R1

7 Exercise 8.3 Gain = - (R2 / R1) = -(150/12) =

8 Can the voltage gain be calculated using the same formula?
Try and use the same method in deriving Vo/Vi

9 Non - Inverting Amplifier
Voltage at node 1 (inverting) = voltage at node 2 (non-inverting ) KCL at node 1: (0– Vi) / R1 = (Vi – Vo) / R2 -(Vi / R1) = (Vi / R2) – (Vo / R2) Vo / R2 = (Vi / R2) + (Vi / R1) = Vi Vo / Vi = R R2 R1 Noninverting amplifier

10 Voltage Follower / Buffer Amplifier
Vo = Vi Hence, gain = 1

11 Summing Amplifier Similarly, i1 + i2 + i3 – i4 – 0 = 0 Example 8.2
Design a summing amplifier as shown in figure to produce a specific output signal, such that vo = 1.25 – 2.5 cos t volt. Assume the input signals are vI1 = -1.0 V, vI2 = 0.5 cos t volt. Assume the feedback resistance RF = 10 k

12 Solution: output voltage

13 Other Op-Amp Applications

14 Integrator Integrator circuit

15 Differentiator Differentiator circuit EXAMPLE 8.4

16 Calculating Gain and Design Questions
NON - INVERTING INVERTING Calculating Output and Design Questions SUMMING AMPLIFIER INTEGRATOR AMPLIFIER DIFFERENTIATOR AMPLIFIER

17 NON - INVERTING INVERTING INVERTING Va Vb Calculate the input voltage if the final output, VO is V.  Then: Vb = -(5/5) Va = - Va Va = V Have to work backwards: Vo = -(100/5) Vb 10.08 = -20 Vb Vb = V Finally: Va = (1 + 10/5) V1 = 3V1 V1 = V

18 What is the value of Vin1 from the figure above?
Vin1 = - 4 V

19 Calculate the output voltage, VO if V1 = V2 = 700 mV
INVERTING SUMMING Va Calculate the output voltage, VO if V1 = V2 = 700 mV Va = -(500/250) 0.7 Va = -1.4 V Then: Vo = [ Va / V2 / 50 ] Vo = [ -1.4 / / 50 ] Vo = 0 V

20 Calculate the output voltage VO of the operational amplifier circuit as shown in the figure.

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