Presentation is loading. Please wait.

Presentation is loading. Please wait.

© From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.1 Op-amp equivalent circuit.

Published byHarvey Taylor Modified over 8 years ago

Similar presentations

Presentation on theme: "© From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.1 Op-amp equivalent circuit."— Presentation transcript:

1 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.1 Op-amp equivalent circuit. The two inputs are  1 and  2. A differential voltage between them causes current flow through the differential resistance R d. The differential voltage is multiplied by A, the gain of the op amp, to generate the output-voltage source. Any current flowing to the output terminal vo must pass through the output resistance R o.

2 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.2 Op-amp circuit symbol. A voltage at v 1, the inverting input, is greatly amplified and inverted to yield  o. A voltage at  2, the noninverting input, is greatly amplified to yield an in-phase output at  o.

3 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.3 (a) An inverting amplified. Current flowing through the input resistor R i also flows through the feedback resistor R f. (b) A lever with arm lengths proportional to resistance values enables the viewer to visualize the input-output characteristics easily. (c) The input-output plot shows a slope of  R f / R i in the central portion, but the output saturates at about ±13 V. RiRi ii oo i RfRf i +  (a) R f R i ii oo (b) 10 V (c) ii oo Slope = -R f / R i -10 V

4 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure E3.1 (a) This circuit sums the input voltage  i plus one-half of the balancing voltage  b. Thus the output voltage  o can be set to zero even when  i has a nonzero dc component. (b) The three waveforms show  i, the input voltage; (  i +  b /2), the balanced-out voltage; and  o, the amplified output voltage. If  i were directly amplified, the op amp would saturate. JH ii v b ii oo oo  + +15V +10 0 Time  i +  b /2 -10 (a)(b) 5 k  -15 V RbRb 20 k  RiRi 10 k  RfRf 100 k  Voltage, V

5 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.4 (a) A follower,  o =  i. (b) A noninverting amplifier,  i appears across R i, producing a current through R i that also flows through R f. (c) A lever with arm lengths proportional to resistance values makes possible an easy visualization of input-output characteristic. (d) The input-output plot shows a positive slope of (R f + R i )/R i in the central portion, but the output saturates at about ±13 V. oo 10 V RfRf RiRi ii oo ii Slope = (R f + R i )/ R i -10 V (c)(d) RfRf oo oo ii ii i + - +  i RiRi (a)(b)

6 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.5 (a) The right side shows a one-op-amp differential amplifier, but it has low input impedance. The left side shows how two additional op amps can provide high input impedance and gain. (b) For the one-op- amp differential amplifier, two levers with arm lengths proportional to resistance values make possible an easy visualization of input-output characteristics.

7 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.6 (a) Comparator. When R 3 = 0,  o indicates whether (  i +  Ref ) is greater or less than 0 V. When R 3 is larger, the comparator has hysteresis, as shown in (b), the input-output characteristic. ii oo oo ii -  ref  + (a)(b) R1R1 R1R1 R2R2 R3R3  ref 10 V -10 V With hysteresis -10 V 10 V Without hysteresis (R 3 = 0) (R 3 > 0)

8 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.7 (a) Full-wave precision rectifier. For  i > 0, the noninverting amplifier at the top is active, making  o > 0. For  i 0. Circuit gain may be adjusted with a single pot. (b) Input-output characteristics show saturation when  o > +13 V. (Reprinted with permission from Electronics Magazine, copyright  December 12, 1974; Penton Publishing, Inc.) (c) One-op-amp full-wave rectifier. For  i 0, the op amp disconnects and the passive resistor chain yields a gain of +0.5. 10 V (b) - 10 V oo ii 10 V  + (a) D3D3 R R o=o= ii  + D2D2 D1D1 D4D4 xR (1-x)R ii x (c) D v o ii  + R i = 2 k  R f = 1 k  R L = 3 k 

9 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.8 (a) A logarithmic amplifier makes use of the fact that a transistor's V BE is related to the logarithm of its collector current. With the switch thrown in the alternate position, the circuit gain is increased by 10. (b) Input-output characteristics show that the logarithmic relation is obtained for only one polarity;  1 and  10 gains are indicated. (a)(b) RfRf IcIc R f /9 oo RiRi ii  + 10 V -10 V v o ii 11  10 10 V

10 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.9 A three-mode integrator With S 1 open and S 2 closed, the dc circuit behaves as an inverting amplifier. Thus  o =  ic and  o can be set to any desired initial conduction. With S 1 closed and S 2 open, the circuit integrates. With both switches open, the circuit holds  o constant, making possible a leisurely readout.

11 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.10 Bode plot (gain versus frequency) for various filters. Integrator (I); differentiator (D); low pass (LP), 1, 2, 3 section (pole); high pass (HP);bandpass (BP). Corner frequencies f c for high-pass, low-pass, and bandpass filters. 100 10 1 0.1 HP BP LP 321 1 k100 Frequency, Hz 10 fcfc 1 D I fcfc

12 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure E3.2 The charge amplifier transfers charge generated from a piezo-electric sensor to the op-amp feedback capacitor C. R + FET Piezo-electric sensor   C isis isRisR isCisC dq s / dt = i s = K dx/dt

13 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.11 A differentiator The dashed lines indicate that a small capacitor must usually be added across the feedback resistor to prevent oscillation.

14 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.12 Active filters (a) A low-pass filter attenuates high frequencies (b) A high-pass filter attenuates low frequencies and blocks dc. (c) A bandpass filter attenuates both low and high frequencies. +  ii oo CiCi +  RiRi ii oo +  RiRi RfRf (a) (b) (c) CfCf ii oo JH RfRf CfCf RfRf CiCi RiRi

15 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.13 Op-amp frequency characteristics early op amps (such as the 709) were uncompensated, had a gain greater than 1 when the phase shift was equal to –180º, and therefore oscillated unless compensation was added externally. A popular op amp, the 411, is compensated internally, so for a gain greater than 1, the phase shift is limited to –90º. When feedback resistors are added to build an amplifier circuit, the loop gain on this log-log plot is the difference between the op- amp gain and the amplifier- circuit gain.

16 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.14 Noise sources in an op amp The noise-voltage source v n is in series with the input and cannot be reduced. The noise added by the noise-current sources In can be minimized by using small external resistances. R1R1 inin inin +  +  +  11 nn dd oo AdAd 22 R2R2

17 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.15 The amplifier input impedance is much higher than the op-amp input impedance R d. The amplifier output impedance is much smaller than the op-amp output impedance R o. +  RdRd i RoRo RLRL CLCL ioio AdAd dd oo ii + 

18 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.16 Functional operation of a phase-sensitive demodulator (a) Switching function. (b) Switch. (c), (e), (g), (i) Several input voltages. (d), (f), (h), (j) Corresponding output voltages.

19 © From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.17 A ring demodulator This phase-sensitive detector produces a full-wave- rectified output  o that is positive when the input voltage  i is in phase with the carrier voltage  c and negative when  i is 180º out of phase with  c.

Download ppt "© From J. G. Webster (ed.), Medical instrumentation: application and design. 3 rd ed. New York: John Wiley & Sons, 1998. Figure 3.1 Op-amp equivalent circuit."

Similar presentations

Introduction Goal: Understand the design of op-amp based ICs (comparators, oscillators, integrators, differentiators, instrumentation amplifiers) for applications.

Introduction Goal: Understand the design of op-amp based ICs (comparators, oscillators, integrators, differentiators, instrumentation amplifiers) for applications.
Operational Amplifiers 1. Copyright  2004 by Oxford University Press, Inc. Microelectronic Circuits - Fifth Edition Sedra/Smith2 Figure 2.1 Circuit symbol.

Operational Amplifiers 1. Copyright  2004 by Oxford University Press, Inc. Microelectronic Circuits - Fifth Edition Sedra/Smith2 Figure 2.1 Circuit symbol.
Experiment 17 A Differentiator Circuit

Experiment 17 A Differentiator Circuit
Chapter 3. Amplifiers and Signal Processing John G. Webster

Chapter 3. Amplifiers and Signal Processing John G. Webster
ENTC 3320 Absolute Value.

ENTC 3320 Absolute Value.
Greg Henderson Abdul Jaroudi Nishanth Mehanathan.

Greg Henderson Abdul Jaroudi Nishanth Mehanathan.
Describe and analyze the operation of several types of comparator circuits. Describe and analyze the operation of several types of summing amplifiers.

Describe and analyze the operation of several types of comparator circuits. Describe and analyze the operation of several types of summing amplifiers.
Principles & Applications Operational Amplifiers

Principles & Applications Operational Amplifiers
Op-Amp With Complex Impedance -+-+ Z1Z1 Vin ZLZL ZFZF VoVo A v = - (Z F /Z 1 ) “-” : 180° phase shift Z = a ± j b Z = M

Op-Amp With Complex Impedance -+-+ Z1Z1 Vin ZLZL ZFZF VoVo A v = - (Z F /Z 1 ) “-” : 180° phase shift Z = a ± j b Z = M
8C120 - 2010 Inleiding Meten en Modellen – 8C120 Prof.dr.ir. Bart ter Haar Romeny Dr. Andrea Fuster Faculteit Biomedische Technologie Biomedische Beeld.

8C Inleiding Meten en Modellen – 8C120 Prof.dr.ir. Bart ter Haar Romeny Dr. Andrea Fuster Faculteit Biomedische Technologie Biomedische Beeld.
Lecture 91 Loop Analysis (3.2) Circuits with Op-Amps (3.3) Prof. Phillips February 19, 2003.

Lecture 91 Loop Analysis (3.2) Circuits with Op-Amps (3.3) Prof. Phillips February 19, 2003.
Waveform-Shaping Circuits

Waveform-Shaping Circuits
Op Amps Lecture 30.

Op Amps Lecture 30.
Chapter 3. Amplifiers and Signal Processing John G. Webster

Chapter 3. Amplifiers and Signal Processing John G. Webster
1 ECE 3336 Introduction to Circuits & Electronics MORE on Operational Amplifiers Spring 2015, TUE&TH 5:30-7:00 pm Dr. Wanda Wosik Set #14.

1 ECE 3336 Introduction to Circuits & Electronics MORE on Operational Amplifiers Spring 2015, TUE&TH 5:30-7:00 pm Dr. Wanda Wosik Set #14.
Astable multivibrators I

Astable multivibrators I
Prof. Yasser Mostafa Kadah – www.k-space.org BASIC ELECTRONICS PART 4: OPERATIONAL AMPLIFIER.

Prof. Yasser Mostafa Kadah – BASIC ELECTRONICS PART 4: OPERATIONAL AMPLIFIER.
Introduction to Op Amps

Introduction to Op Amps
Chapter 31 Applications of Op-Amps. 2 Comparators Op-amp as a Comparator –No negative feedback –Output saturates with very small + or – input.

Chapter 31 Applications of Op-Amps. 2 Comparators Op-amp as a Comparator –No negative feedback –Output saturates with very small + or – input.
Operational Amplifiers

Operational Amplifiers

Similar presentations

Ads by Google