1. 4. OPERATIONAL AMPLIFIERS CIRCUITS by Ulaby & Maharbiz All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

2. All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

3. Tech Brief 5: IC Fabrication Wafer: Thin slice of semiconductor material with highly polished surface Processed wafer is cut into many dies or chips. Lithography: Defining spatial pattern Photoresist: Polymer material that does not allow etching or deposition of areas underneath it. All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

4. Tech Brief 5: IC Fabrication All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

5. Lithography: Defining spatial pattern Photoresist: Polymer material that does not allow etching or deposition of areas underneath it. Tech Brief 5: IC Fabrication All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

6. Tech Brief 5: IC Fabrication All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

7. Tech Brief 5: IC Fabrication All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

8. Tech Brief 5: IC Fabrication All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

9. Operational Amplifier “Op Amp”  Two input terminals, positive (non- inverting) and negative (inverting)  One output  Power supply V +, and Op Amp showing power supply Op Amp with power supply not shown (which is how we usually display op amp circuits) All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

10. Inside The Op-Amp (741) All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

11. Gain  Key important aspect of op amp: high voltage gain  Output, A is op-amp gain (or open-loop gain) – different from circuit gain G  Linear response All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

12. Equivalent Circuit All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

13. Example 4-1: Op Amp Amplifier KCL at Node a: KCL at Node b: For infinite A: = 4.999975 = 5 Node a Node b All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

14. Negative Feedback  Feedback: return some of the output to the input  Negative feedback decreases input signal  Achieves desired circuit gain, with wide range for input Negative Feedback No Feedback Range of 5 Gain = 5Range of : ‒ 2 V to +2 V Gain = 1million Range of : ‒ 10 mV to +10 mV All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

15. Negative Feedback All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

16. Circuit Analysis With Ideal Op Amps  Use nodal analysis as before, but with “golden rules”   N  Do not apply KCL at op amp output No current into op amp No voltage drop across op amp input All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

17. Noninverting Amplifier (max) = V cc At node All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

18. Inverting Amplifier All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

19. Example 4-2: Input Current Source Relate output voltage to input current source All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

20. Summing Amplifier All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

21. Example 4-3: Solution: All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

22. Difference Amplifier Note negative gain of channel 1 All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

23. Voltage Follower “Buffers” Sections of Circuit What is the op amp doing? depends on both input and load resistors is immune to input and load resistors All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

25. Example 4-5: Elevation Sensor Sensor Response Desired Output h = elevation, inversely proportional to air pressure All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

26. Example 4-6: Multiple Op-Amp Circuit All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

27. Measurement Uncertainty (T = 21 ° C) v2v2 V 0 = V 2 ± 1% of V 2 21 ° C ± 0.21 ° C G = 1 ± 1% G = 1 1% G = 1 1% v2v2 (T = 21 ° C) Thermistor v1v1 Fixed Reference Temp = 20 ° C V 0 = (V 2 ‒ V 1 ) ± 1% of (V 2 ‒ V 1 ) 1 ° C ± 0.01 ° C Direct Measurement Differential Measurement Much better measurement uncertainty All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

28. Instrumentation Amplifier Highly sensitive differential amplifier All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

29. Digital to Analog Converter Converts digital value into analog voltage 4-digit example All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

30. Digital to Analog Converter Represent digital value with analog voltage All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

31. MOSFET (Field Effect Transistor) Active Device: Voltage Controlled Current Source Gate voltage controls drain/source current All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

32. MOSFET Equivalent Circuit Characteristic curvesIdealized response All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

33. Example 4-9: MOSFET Amplifier Given: Determine All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

34. Load Line You can use a “load line” to graphically determine V out = V DS for a given V in = V GS RLRL V DD V DD / R D All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

35. Digital Circuit: MOSFET Inverter V DD = 15 V RLRL G S D IDID Output “High” Logic 1 Output “Low” Logic 0 InOut 01 10 Input “Low” InOut V DD 012345 0 5 10 15 V GS =V in V DS =V out Output “Low” Logic 0 Output “High” Logic 1 Input “High” All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

36. Read-Only Memory (ROM) Circuits V READ = 1 V BIT = 0100 All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

37. Another Digital Circuit Element: NAND ABOut 001 011 101 110 A B V DD A V out B No current flows through resistor, unless both A and B inputs turn their transistors on to “pull down” V out NAND gates can be used to build any binary logic function All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

38. Another Digital Circuit Element: NOR Current will flow if either A or B inputs turn their transistors on to “pull down” V out ABOut 001 010 100 110 A B A V DD V out B NOR gates can be used to build any binary logic function All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

39. Example: Multisim Instruments All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

40. Multisim Table All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

42. Multisim: MOSFET I-V Analyzer All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

43. Tech Brief 6: Display Technologies All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

44. Tech Brief 6: Display Technologies Digital Light Processing (DLP) All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

45. Summary All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press