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Lecture 4 Operational Amplifiers—Non-ideal behavior

Lecture 4 Operational Amplifiers—Non-ideal behavior. 1. Goals. Study non-ideal op amp behavior. Demonstrate circuit analysis techniques for non-ideal op amps. Understand frequency response limitations of op amp circuits. 2. Frequency Response of Op Amps: General Case.

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Lecture 4 Operational Amplifiers—Non-ideal behavior

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  1. Lecture 4Operational Amplifiers—Non-ideal behavior 1

  2. Goals • Study non-ideal op amp behavior. • Demonstrate circuit analysis techniques for non-ideal op amps. • Understand frequency response limitations of op amp circuits. 2

  3. Frequency Response of Op Amps: General Case vo = A (v+ - v-) (A) is function of frequency General purpose op-amp has a single-pole response 100db Gain = 105 0 dB Gain = 1 3 Band-width Unity gain frequency

  4. Frequency Response of Op Amps: General Case Op amps: Low-pass amplifier with high gain at dc and a single-pole frequency response. wB= open loop bandwidth of op amp. ωT= unity gain bandwidth (frequency at which magnitude of gain is unity). At w >>wB, At ω =ωT, At w >>wB,product of magnitude of amplifier gain and frequency is a constant value of unity gain frequency. Hence, wT is also called gain-bandwidth product. 4

  5. Frequency Response of Op Amps: General Case (Example) Frequency values are often expressed in Hz. • Problem: Find transfer function describing frequency-dependent amplifier voltage gain. 5

  6. Frequency Response of Op Amps: Noninverting Amplifier 6

  7. Frequency Response of Op Amps: Noninverting Amplifier |Vo/Vin| (dB) Ao -20 dB/dec 1 + R2/R1 f (log scale) f3dB (no feedback) f3dB (with feedback) 7

  8. For a 741 Op amp, ft = 1MHz Gain = 105 (100dB)  f3dB = 1MHz/105 = 10 Hz Gain = 100 (40 dB)  f3dB = 1MHz/100 = 10KHz Gain = 10 (20dB)  f3dB = 1MHz/10 = 100KHz 8

  9. Frequency Response of Op Amps: Noninverting Amplifier (Example) Problem: Characterize frequency response of noninverting amplifier. Given data:Ao= 105= 100 dB, fT= 107 Hz, desired Av= 1000= 60 dB Assumptions: Amplifier is described by single-pole transfer function. Analysis: Noninverting amplifier transfer function 9

  10. Slew Rate (SR) Slew rate: maximum rate of change at the output of the OPAMP 10

  11. Large Signal Limitations: Slew Rate (SR) and Full-Power Bandwidth • Slew rate: Maximum rate of change of voltage at output of op amp.Typical values range from 0.1V/ms to 10V/ms. • For given frequency, slew rate limits maximum signal amplitude that can be amplified without distortion. For no signal distortion, Full-power bandwidth is highest frequency at which a full-scale signal can be developed. 11

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