1: Lecture 2�Operational Amplifiers
3: Ideal Operation Amplifier (Op Amp)
4: Ideal Op Amp Example
5: Ideal Op Amp Example �(Alternative Approach)
6: Operational Amplifier Complete Model Represented by:
A= open-circuit voltage gain
vid = (v+-v-) = differential input signal voltage
Rid = amplifier input resistance
Ro = amplifier output resistance
7: Operational Amplifier Mathematical Model: With Source and Load RL = load resistance
RS = Thevenin equivalent resistance of signal source
vs = Thevenin equivalent voltage of signal source
8: Ideal Operational Amplifier Ideal op amp is a special case of ideal differential amplifier with infinite gain, infinite Rid and zero Ro .
and
If A is infinite, vid is zero for any finite output voltage.
Vid = 0, v+=v- (Virtual Short Model)
Infinite input resistance Rid forces input currents i+ and i- to be zero.
Summary, Ideal op amp has following assumptions:
A=8 , Where A is Open-loop gain
i- = i+ = 0, Input resistance is infinite
Zero output resistance
Infinite bandwidth
9: Inverting Amplifier: Configuration Positive input is grounded.
Feedback network, resistors R1 and R2 connected between inverting input and signal source and amplifier output node respectively.
10: Inverting Amplifier:Voltage Gain Negative voltage gain implies 1800 phase shift between dc/sinusoidal input and output signals.
Gain greater than 1 if R2 > R1
Gain less than 1 if R1 > R2
Inverting input of op amp is at ground potential (not connected directly to ground) and is said to be at virtual ground.
11: Inverting Amplifier: Example
12: Non-inverting Amplifier: Configuration
13: Non-inverting Amplifier:Voltage Gain, Input Resistance and Output Resistance Since i-=0 and
But vid =0
Since i+=0
14: Unity-gain Buffer A special case of non-inverting amplifier, also called voltage follower with infinite R1 and zero R2. Hence Av =1.
Provides excellent impedance-level transformation while maintaining signal voltage level.
Ideal voltage buffer does not require any input current and can drive any desired load resistance without loss of signal voltage.
Unity-gain buffer is used in may sensor and data acquisition systems.
15: Summing Amplifier Scale factors for the 2 inputs can be independently adjusted by proper choice of R2 and R1.
Any number of inputs can be connected to summing junction through extra resistors.
This is an example of a simple digital-to-analog converter.
16: Difference Amplifier
17: Difference Amplifiers
18: Difference Amplifier Also called a differential subtractor, amplifies difference between input signals.
Rin2 is series combination of R1 and R2 because i+ is zero.
For v2=0, Rin1= R1, as the circuit reduces to an inverting amplifier.
For general case, i1 is a function of both v1 and v2.
19: Operational Amplifier Complete Model Represented by:
A= open-circuit voltage gain
vid = (v+-v-) = differential input signal voltage
Rid = amplifier input resistance
Ro = amplifier output resistance
20: Non-ideal Operational Amplifier Various error terms arise in practical operational amplifiers due to non-ideal behavior.
Some of the non-ideal characteristics include:
v Finite open-loop gain that causes gain error
Nonzero output resistance
Finite input resistance
Finite CMRR
Common-mode input resistance
v DC error sources
v Output voltage and current limits
21: Finite Open-loop Gain
