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Lecture 1 Op-Amp • Introduction of Operation Amplifier (OpAmp) • Analysis of ideal Op-Amp applications • Comparison of ideal and non-ideal Op-Amp • Non-ideal Op-Amp consideration Operational Amplifier (Op-Amp) +Vcc Very high differential gain Input 1 + High input impedance Vo Vd Low output impedance Output Provide voltage changes Input 2 (amplitude and polarity) Rin~inf -Vcc Rout~0 • Used in oscillator, filter Vo GdVd and instrumentation • Accumulate a very high Gd : differenti al gain normally gain by multiple stages 5 • • • • ver y large, say 10 IC Product OFFSET NULL -IN 1 8 N.C. 2 7 V+ 6 OUTPUT 5 OFFSET NULL +IN 3 V 4 + DIP-741 OUTPUT A 1 -IN A 2 +IN A 3 V 4 8 V+ + 7 OUTPUT B 6 + 5 +IN B -IN B Dual op-amp 1458 device Single-Ended Input + ~ Vi V o + V o ~ V i • + terminal : Source • – terminal : Ground • 0o phase change • + terminal : Ground • – terminal : Source • 180o phase change Double-Ended Input V + d ~ • Differential input V o • Vd V V • 0o phase shift change between Vo and Vd + ~ V1 V o Qu: What Vo should be if, V 2 ~ V 2 V 1 Ans: (A or B) ? (A) (B) Distortion +V =+5V cc + V V +5V o d 0 5V V =5V cc The output voltage never excess the DC voltage supply of the Op-Amp Common-Mode Operation • Same voltage source is applied at both terminals + • Ideally, two input are equally amplified • Output voltage is ideally zero due to differential voltage is zero • Practically, a small output signal can still be measured V o V i ~ Note for differential circuits: Opposite inputs : highly amplified Common inputs : slightly amplified Common-Mode Rejection Common-Mode Rejection Ratio (CMRR) Differential voltage input : Vd V V Noninverting + Input Output Common voltage input : 1 Vc (V V ) 2 Output voltage : Vo Gd Vd GcVc Gd : Differential gain Gc : Common mode gain Inverting Input Common-mode rejection ratio: CMRR Gd G 20 log 10 d (dB) Gc Gc Note: When Gd >> Gc or CMRR Vo = GdVd CMRR Example What is the CMRR? 100V 100V + 60700V 80600V 20V + 40V Solution : Vd 1 100 20 80V (1) Vd 2 100 40 60V 100 20 100 40 60V Vc 2 70V 2 2 From (1) Vo 80Gd 60Gc 80600V Vc1 From (2) Gd 1000 (2) Vo 60Gd 70Gc 60700V and Gc 10 CMRR 20 log( 1000 / 10) 40dB NB: This method is Not work! Why? Op-Amp Properties (1) Infinite Open Loop gain - The gain without feedback Equal to differential gain Zero common-mode gain Pratically, Gd = 20,000 to 200,000 V1 + V2 i1~0 + i2~0 (2) Infinite Input impedance - Input current ii ~0A T- in high-grade op-amp m-A input current in low-grade op-amp (3) Zero Output Impedance - act as perfect internal voltage source No internal resistance Output impedance in series with load Reducing output voltage to the load Practically, Rout ~ 20-100 Vo Vo Rout Vo' + Vload Rload Rload Vo Rload Rout Frequency-Gain Relation • • • • • Ideally, signals are amplified from DC to the highest AC (Voltage Gain) frequency Gd Practically, bandwidth is limited 0.707Gd 741 family op-amp have an limit bandwidth of few KHz. Unity Gain frequency f1: the gain at unity Cutoff frequency fc: the gain drop by 3dB from dc gain Gd 20log(0.707)=3dB 1 0 fc f1 (frequency) GB Product : f1 = Gd fc GB Product Example: Determine the cutoff frequency of an op-amp having a unit gain frequency f1 = 10 MHz and voltage differential gain Gd = 20V/mV (Voltage Gain) Sol: Since f1 = 10 MHz Gd 0.707Gd ? Hz By using GB production equation f1 = Gd fc 10MHz fc = f1 / Gd = 10 MHz / 20 V/mV = 10 106 / 20 103 = 500 Hz 1 0 fc f1 (frequency) Ideal Vs Practical Op-Amp Ideal Practical Open Loop gain A 105 Bandwidth BW 10-100Hz Input Impedance Zin >1M 0 10-100 Depends only on Vd = (V+V) Differential mode signal Depends slightly on average input Vc = (V++V)/2 Common-Mode signal 10-100dB Output Impedance Zout Output Voltage Vout CMRR Ideal op-amp + AVin Vin Vout ~ Zout=0 Practical op-amp + Vin Zout Zin ~ AVin Vout Ideal Op-Amp Applications Analysis Method : Two ideal Op-Amp Properties: (1) The voltage between V+ and V is zero V+ = V (2) The current into both V+ and V termainals is zero For ideal Op-Amp circuit: (1) Write the kirchhoff node equation at the noninverting terminal V+ (2) Write the kirchhoff node eqaution at the inverting terminal V (3) Set V+ = V and solve for the desired closed-loop gain Noninverting Amplifier (1) Kirchhoff node equation at V+ yields, V V V + in V o i (2) Kirchhoff node equation at V yields, V 0 V Vo Ra (3) Rf 0 Setting V+ = V– yields Vi Vi Vo 0 or Ra Rf Rf Vo 1 Vi Ra Ra Rf v+ vi v- + v+ vo R 1 Rf v+ v- Rf Ra 2 v- )vi Rf Voltage follower o R f Noninverting input with voltage divider Rf R2 vo (1 )( )vi Ra R1 R2 v v+ i vo v a + vo vi R R Noninverting amplifier vo (1 + i Ra vi v R 1 R 2 v- + v o R f Less than unity gain R2 vo vi R1 R2 Inverting Amplifier (1) Rf Kirchhoff node equation at V+ yields, V 0 Ra (2) Kirchhoff node equation at V yields, Vin V_ V V o 0 Ra Rf (3) Setting V+ = V– yields Vo R f Vin Ra V ~ in V o + Notice: The closed-loop gain Vo/Vin is dependent upon the ratio of two resistors, and is independent of the open-loop gain. This is caused by the use of feedback output voltage to subtract from the input voltage. Multiple Inputs (1) Kirchhoff node equation at V+ yields, V 0 (2) Kirchhoff node equation at V yields, V_ Vo Rf (3) Rf Va Vb Vc V Va V Vb V Vc 0 Ra Rb Rc Setting V+ = V– yields c V Va Vb Vc j Vo R f R f j a R j Ra Rb Rc Ra Rb Rc V o + Inverting Integrator Now replace resistors Ra and Rf by complex components Za and Zf, respectively, therefore Zf Vo Vin Supposing Za (i) The feedback component is a capacitor C, in i.e., 1 Zf (ii) The input component is a resistor R, Za = R jC Therefore, the closed-loop gain (Vo/Vin) become: Zf Za where vi (t ) Vi e jt What happens if Za = 1/jC whereas, Zf = R? Inverting differentiator + C R V ~ in V o V ~ 1 vo (t ) vi (t )dt RC V o + Op-Amp Integrator Example: (a) Determine the rate of change of the output voltage. C R +5V 0 100s (b) Draw the output waveform. V i 10 k 0.01F V o + Vo(max)=10 V Solution: (a) Rate of change of the output voltage Vo V 5V i t RC (10 k)(0.01 F) 50 mV/ s +5V 0 V i 0 (b) In 100 s, the voltage decrease Vo (50 mV/ s)(100μs) 5V -5V -10V V o Op-Amp Differentiator R C 0 to t1 t2 V i V o 0 + to dV vo i RC dt t1 t2 Non-ideal case (Inverting Amplifier) Rf Ra Vin ~ V in Practical op-amp + V o + Equivalent Circuit Rf Ra R R V + + -AV Vin Zout Zin ~ Vout AVin 3 categories are considering V o Close-Loop Voltage Gain Input impedance Output impedance Close-Loop Gain Applied KCL at V– terminal, Vin V V Vo V 0 Ra R Rf By using the open loop gain, Rf V Ra in V R R + + Vo AV Vin Vo V V V o o o 0 Vin Ra ARa AR R f AR f R R Ra R f Ra R ARa R Vin Vo f Ra ARa R R f The Close-Loop Gain, Av AR R f Vo Av Vin R R f Ra R f Ra R ARa R Ra V o -AV Rf V o V R Close-Loop Gain When the open loop gain is very large, the above equation become, Av ~ Rf Ra Note : The close-loop gain now reduce to the same form as an ideal case Input Impedance Rf Input Impedance can be regarded as, Rin Ra R // R where R is the equivalent impedance of the red box circuit, that is V R if However, with the below circuit, V ( AV ) i f ( R f Ro ) V R f Ro R if 1 A V Ra in R V R + + -AV R' if Rf R V + -AV V o Input Impedance Finally, we find the input impedance as, 1 1 A Rin Ra R R R f o 1 Rin Ra R ( R f Ro ) R f Ro (1 A) R Since, R f Ro (1 A) R , Rin become, Rin ~ Ra ( R f Ro ) (1 A) Again with R f Ro (1 A) Rin ~ Ra Note: The op-amp can provide an impedance isolated from input to output Output Impedance Only source-free output impedance would be considered, i.e. Vi is assumed to be 0 Firstly, with figure (a), V Rf Ra Ra // R Ra R Vo V Vo R f Ra // R Ra R f Ra R R f R R V By using KCL, io = i1+ i2 Vo V ( AV ) io o R f Ra // R f Ro io R V + -AV By substitute the equation from Fig. (a), The output impedance, Rout is Ro ( Ra R f Ra R R f R ) Vo io (1 Ro )( Ra R f Ra R R f R ) (1 A) Ra R R and A comparably large, Ro ( Ra R f ) Rout ~ ARa Rf V i2 R V Ra R (a) i1 V + -AV (b) o