1 / 52

EMT 212/4 ANALOG ELECTRONIC II CHAPTER 2: OP-AMP APPLICATIONS & FREQUENCY RESPONSE

EMT 212/4 ANALOG ELECTRONIC II CHAPTER 2: OP-AMP APPLICATIONS & FREQUENCY RESPONSE. Content. Op-amp Application Introduction Inverting Amplifier Non-inverting Amplifier Voltage Follower / Buffer Amplifier Summing Amplifier Differencing Amplifier Integrator Differentiator Comparator

phillipdaniels
Download Presentation

EMT 212/4 ANALOG ELECTRONIC II CHAPTER 2: OP-AMP APPLICATIONS & FREQUENCY RESPONSE

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. EMT 212/4 ANALOG ELECTRONIC IICHAPTER 2:OP-AMP APPLICATIONS & FREQUENCY RESPONSE

  2. Content • Op-amp Application • Introduction • Inverting Amplifier • Non-inverting Amplifier • Voltage Follower / Buffer Amplifier • Summing Amplifier • Differencing Amplifier • Integrator • Differentiator • Comparator • Summary • Frequency Response

  3. Op-amp Application • Introduction Op-amps are used in many different applications. We will discuss the operation of the fundamental op-amp applications. Keep in mind that the basic operation and characteristics of the op-amps do not change — the only thing that changes is how we use them

  4. Inverting Amplifier • Circuit consists of an op-amp and three resistors. • The positive (+) input to the op-amp is grounded through R2. • The negative (-) input is connected to the input signal (via R1) and also to the feedback signal from the output (via RF).

  5. Inverting Amplifier • Assume that amplifier operates in its linearly amplifying region. • For an ideal op-amp, the difference between the input voltages V+ and V to the op-amp is very small, essentially zero;

  6. Inverting Amplifier • Hence;

  7. Inverting Amplifier • The op-amp input resistance is large, so the current into the +ve and –ve op-amp inputs terminal will be small, essentially zero

  8. Inverting Amplifier • Currents and voltages in the inverting op-amp

  9. Inverting Amplifier - Example • Design an inverting amplifier with a specified voltage gain. Specification: Design the circuit such that the voltage gain is Av = -5. Assume the op-amp is driven by an ideal sinusoidal source, vs = 0.1sin wt (V), that can supply a maximum current of 5 µA. Assume that frequency w is low so that any frequency effects can be neglected.

  10. Non-Inverting Amplifier • Circuit consists of an op-amp and three resistors. • The negative (-) input to the op-amp is grounded through R1 and also to the feedback signal from the output (via RF). • The positive (+) input is connected to the input signal.

  11. Non-Inverting Amplifier • Input current to op-amp is very small. No signal voltage is created across R2 and hence • so it follows that;

  12. Non-Inverting Amplifier • so RFand R1carry the same current. Hence vout is related to V through a voltage-divider relationship

  13. Non-Inverting Amplifier • The output has the same polarity as the input, • a positive input signal produces a positive output signal. • The ratio of R1and RFdetermines the gain. • When a voltage is applied to the amplifier, the output voltage increases rapidly and will continue to rise until the voltage across R1reaches the input voltage. Thus negligible input current will flow into the amplifier, and the gain depends only on R1and RF

  14. Non-Inverting Amplifier • The input resistance to the non-inverting amplifier is very high because the input current to the amplifier is also the input current to the op-amp, I+, which must be extremely small.

  15. Non-Inverting Amplifier

  16. Voltage Follower / Buffer Amplifier • This “buffer” is used to control impedance levels in the circuit – it isolates part of the overall (measurement) circuit from the output (driver). • The input impedance to the buffer is very high and its output impedance is low. • The output voltage from a source with high output impedance can, via the buffer, supply signal to one or more loads that have a low impedance.

  17. Voltage Follower / Buffer Amplifier • High input impedance. • Low output impedance. • Voltage gain = 1

  18. Summing Amplifier • The inverting amplifier can accept two or more inputs and produce a weighted sum. • Using the same reasoning as with the inverting amplifier, that V≈ 0. • The sum of the currents through R1, R2,…,Rnis:

  19. Summing Amplifier • The op-amp adjusts itself to draw iin through Rf(iin = if). • The output will thus be the sum of V1,V2,…,Vn, weighted by the gain factors, Rf/R1 , Rf/R2 ….., Rf/Rn respectively.

  20. Summing Amplifier • Special Cases for this Circuit: 1. If R1 = R2 =……= R then:

  21. Summing Amplifier 2. If R1= R2= … = R and VIN1, VIN2, … are either 0V (digital “0”) or 5V (digital “1”) then the output voltage is now proportional to the number of (digital) 1’s input.

  22. Summing Amplifier - Application • Digital to Analog Converter - binary-weighted resistor DAC

  23. Summing Amplifier - Application • Digital to Analog Converter - R/2R Ladder DAC

  24. Differencing Amplifier • This circuit produces an output which is proportional to the difference between the two inputs

  25. Differencing Amplifier • The circuit is linear so we can look at the output due to each input individually and then add them (superposition theorem)

  26. Differencing Amplifier • Set v1 to zero. The output due to v2 is the same as the inverting amplifier, so

  27. Differencing Amplifier • The signal to the non-inverting output, is reduced by the voltage divider:

  28. Differencing Amplifier • The output due to this is then that for a non-inverting amplifier:

  29. Differencing Amplifier

  30. Differencing Amplifier • Thus the output is: • Thus the amplifier subtracts the inputs and amplifies their difference.

  31. Integrator • The basicintegrator is easily identified by the capacitor in the feedback loop. • A constant input voltage yields a ramp output. The input resistor and the capacitor form an RC circuit.

  32. Integrator • The slope of the ramp is determined by the RC time constant. • The integrator can be used to change a square wave input into a triangular wave output.

  33. Integrator • The capacitive impedance:

  34. Integrator • The input current:

  35. Integrator

  36. Integrator • Thus the output in time domain:

  37. Differentiator

  38. Differentiator • The differentiator does the opposite of the integrator in that it takes a sloping input and provides an output that is proportional to the rate of change of the input. • Note the capacitor is in the input circuit. • The output voltage can be determined by the formula below:

  39. Comparator • The comparator is an op-amp circuit that compares two input voltages and produces an output indicating the relationship between them. • The inputs can be two signals (such as two sine waves) or a signal and a fixed dc reference voltage. • Comparators are most commonly used in digital applications.

  40. Comparator • Digital circuits respond to rectangular or square waves, rather than sine waves. • These waveforms are made up of alternating (high and low) dc levels and the transitions between them.

  41. Comparator • Example: Assume that the digital system is designed to perform a specific function when a sine wave input reaches a value of 10 V

  42. Comparator

  43. Comparator • With nonzero-level detection the voltage divider or zener diode sets the reference voltage at which the op-amp turns goes to the maximum voltage level.

  44. Comparator

  45. Comparator • Remember that the comparator is configured in open-loop, making the gain very high. This is open-loop configuration. • This makes the comparator very susceptible to unwanted signals (noise) that could cause the output to arbitrarily switch states.

  46. Comparator • If the level of the pulse must be less than the output of a saturated op-amp, a zener-diode can be used to limit the output to a particular voltage. This is called output bounding. • Either positive, negative, or both halves of the output signal can be bounded by use of one or two zener diodes respectively

  47. Comparator - Application • Over-Temperature Sensing circuit

  48. Comparator - Application • Analog to Digital Converter

  49. Summary • The summing amplifier’s output is the sum of the inputs. • An averaging amplifier yields an output that is the average of all the inputs. • The scaling adder has inputs of different weight with each contributing more or less to the input. • Integrators change a constant voltage input to a sloped output. • Differentiators change a sloping input into a step voltage proportional to the rate of change. • The op-amp comparator’s output changes state when the input voltage exceeds the reference voltage.

  50. Frequency Response of Op-amp • The “frequency response” of any circuit is the magnitude of the gain in decibels (dB) as a function of the frequency of the input signal. • The decibel is a common unit of measurement for the relative magnitude of two power levels. The expression for such a ratio of power is: • Note: A decibel is one-tenth of a "Bel", a seldom-used unit named for Alexander Graham Bell, inventor of the telephone. Power level in dB = 10log10(P1/P2)

More Related