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Analog Electronics

Analog Electronics. Lecture 5. Operational Amplifers. Op-amp is an electronic device that amplify the difference of voltage at its two inputs. Most op-amps operate from plus and minus supply voltages, which may or may not be shown on the schematic symbol.

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Analog Electronics

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  1. Analog Electronics Lecture 5

  2. Operational Amplifers Op-amp is an electronic device that amplify the difference of voltage at its two inputs. Most op-amps operate from plus and minus supply voltages, which may or may not be shown on the schematic symbol. Very high gain dc coupled amplifiers with differential inputs. One of the inputs is called the inverting input (-); the other is called the non-inverting input. Usually there is a single output.

  3. The Ideal Op-Amp • Ideally, op-amps have characteristics (used in circuit analysis): • Infinite voltage gain • Infinite input impedance (does not load the driving sources) • Zero output impedance (drive any load) • Infinite bandwidth (flat magnitude response, zero phase shift) • Zero input offset voltage. The ideal op-amp has characteristics that simplify analysis of op-amp circuits. The concept of infinite input impedance is particularly a valuable analysis tool for several op-amp configurations.

  4. The Practical Op-Amp Real op-amps differ from the ideal model in various respects. In addition to finite gain, bandwidth, and input impedance, they have other limitations. • Finite open loop gain. • Finite input impedence. • Non-zero output impedence. • Input current. • Input offset voltage. • Temperature effects.

  5. Input and Output Impedances

  6. Input Signal modes The input signal can be applied to an op-amp in differential-mode or in common-mode. Differential-mode signals are applied either as single-ended (one side on ground) or double-ended (opposite phases on the inputs).

  7. Signal modes Common-mode signals are applied to both sides with the same phase on both. Usually, common-mode signals are from unwanted sources, and affect both inputs in the same way. The result is that they are essentially cancelled at the output. Common-mode signals

  8. Common-Mode Rejection Ratio The ability of an amplifier to amplify differential signals and reject common-mode signals is called the common-mode rejection ratio (CMRR). where Aol is the open-loop differential-gain and Acm is the common-mode gain. CMRR is defined as Acmis zero in ideal op-amp and much less than 1 is practical op-amps. Aol ranges up to 200,000 (106dB) CMRR = 100,000 means that desired signal is amplified 100,000 times more than un wanted noise signal. CMRR can also be expressed in decibels as

  9. Example Common-Mode Rejection Ratio What is CMRR in decibels for a typical 741C op-amp? The typical open-loop differential gain for the 741C is 200,000 and the typical common-mode gain is 6.3. 90 dB (The minimum specified CMRR is 70 dB.)

  10. Current Offsets IBIAS: The input bias current is the average of the two dc currents required to bias the differential amplifier VOUT(ERR) = AvIos.Rin IOS: The input offset current is the difference between the two dc bias currents Vos = Ios.Rin

  11. Schematic

  12. Voltage and Current Parameters VO(p-p): The maximum output voltage swing is determined by the op-amp and the power supply voltages VOS: The input offset voltage is the differential dc voltage required between the inputs to force the output to zero volts IBIAS: The input bias current is the average of the two dc currents required to bias the differential amplifier IOS: The input offset current is the difference between the two dc bias currents

  13. Impedance Parameters ZIN(d) : The differential input impedance is the total resistance between the inputs ZIN(cm) : The common-mode input impedance is the resistance between each input and ground Zout:The output impedance is the resistance viewed from the output of the circuit.

  14. Slew Rate Slew rate: The slew rate is the maximum rate of change of the output voltage in response to a step input voltage Determine the slew rate for the output response to a step input. =6 V/ms

  15. Extremely High Gain Open loop gain of an op-amp is in order of 100,000. Even an extremely small input such as input offset voltage can saturate the out put. Vin * Aol= (1mv * 100,1000) = 100V It limits the use to comparator. It is not well-controlled parameter.

  16. Negative Feedback One of the most useful concepts in electronics Negative feedback is the process of returning a portion of the output signal to the input with a phase angle that opposes the input signal. The advantage of negative feedback is that precise values of amplifier gain can be set. In addition, bandwidth and input and output impedances can be controlled. The gain with external feedback is called closed loop gain, Acl

  17. Noninverting Amplifier A noninverting amplifier is a configuration in which the signal is given on the noninverting input and a portion of the output is returned to the inverting input. The difference of input voltage, Vin and the feedback voltage Vfis the differential input to op-amp . Difference is amplified with Aol The closed-loop gain of the noninverting amplifier is

  18. Example Noninverting Amplifier Determine the gain of the noninverting amplifier shown. = 25.8

  19. Voltage Follower A special case of the inverting amplifier is when Rf =0 and Ri= ∞. This forms a voltage follower or unity gain buffer with a gain of 1. This configuration offers very high input impedance and its very low output impedance. These features make it a nearly ideal buffer amplifier for interfacing high-impedance sources and low-impedance loads. It produces an excellent circuit for isolating one circuit stage from another, which avoids "loading" effects.

  20. Inverting Amplifier An inverting amplifier is a configuration in which the noninverting input is grounded and the signal is applied through a resistor to the inverting input. Concepts of infinite open loop gain and infinite input resistance extends to ’virtual ground’ at inverting input. Current through Riand through Rf is equal as no current to the inverting input. Iin If The closed-loop gain of the inverting amplifier is I1=0 0 V (virtual ground)

  21. Example Inverting Amplifier Determine the gain of the inverting amplifier shown. = -24.8 The minus sign indicates phase inversion.

  22. Impedances Noninverting amplifier:

  23. Impedances Inverting amplifier: Note that the output impedance has the same form for both amplifiers.

  24. Impedances Noninverting amplifier: Generally, assumed to be ∞ Generally, assumed to be 0 Inverting amplifier: Generally, assumed to be Ri Generally, assumed to be 0 Note that the output impedance has the same form for both amplifiers.

  25. Bias Current and Offset voltage with compensation techniques • Transistors within op-amp need bias current. • Practical op-amp has small input bias currents. • Small imbalances in transistors produce a small offset voltage between the inputs.

  26. Bias Current and Offset voltage with compensation techniques

  27. Bias Current Compensation To compensate for input offset current, a resistor equal to Ri||Rfis added to one of the inputs. Noninverting amplifier Inverting amplifier

  28. Input Offset Voltage Compensation Most ICs provide a mean of compensation. An external potentiometer to the offset null pins of IC package

  29. Bandwidth Limitations Many op-amps have a roll off rate determined by a single low-pass RC circuit, giving a constant -20 dB/decade down to unity gain. The blue line represents the open-loop frequency characteristic (Bode plot) for the op-amp.

  30. Bandwidth Limitations For op-amps with a -20 dB/decade open-loop gain, the closed-loop critical frequency is given by fc(cl) = fc(ol)(1 + BAol(mid)) The closed-loop critical frequency is higher than the open-loop critical frequency by the factor (1 + BAol(mid)). This means that you can achieve a higher BW by accepting less gain. For a compensated op-amp, Acl f(cl) = Aolfc(ol). .

  31. Example Bandwidth Limitations The equation, Acl f(cl) = Aolfc(ol) shows that the product of the gain and bandwidth are constant. The gain-bandwidth product is also equal to the unity gain frequency. That is fT = Aclfc(cl),where fT is the unity-gain bandwidth. The fT for a 741C op amp is 1 MHz. What is the BWcl for the amplifier? 38.8 kHz

  32. Selected Key Terms A type of amplifier that has very high voltage gain, very high input impedance, very low output impedance and good rejection of common-mode signals. Operational amplifier Differential mode Common mode A mode of op-amp operation in which two opposite-polarity signals voltages are applied to the two inputs (double-ended) or in which a signal is applied to one input and ground to the other input (single-ended). A condition characterized by the presence of the same signal on both inputs

  33. Selected Key Terms The voltage gain of an op-amp without external feedback. Open-loop voltage gain Negative feedback Closed-loop voltage gain Gain-bandwidth product The process of returning a portion of the output signal to the input of an amplifier such that it is out of phase with the input. The voltage gain of an op-amp with external feedback. A constant parameter which is always equal to the frequency at which the op-amp’s open-loop gain is unity (1).

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