Book contents
- Frontmatter
- Contents
- List of figures
- List of tables
- About the authors
- To the Reader
- Acknowledgments
- Introduction
- 1 Equipment familiarization: multimeter, breadboard, and oscilloscope
- 2 RC circuits
- 3 Diodes
- 4 Bipolar transistors
- 5 Transistors II: FETs
- 6 Transistors III: differential amplifier
- 7 Introduction to operational amplifiers
- 8 More op amp applications
- 9 Comparators and oscillators
- 10 Combinational logic
- 11 Flip-flops: saving a logic state
- 12 Monostables, counters, multiplexers, and RAM
- 13 Digital↔analog conversion
- Further reading
- Appendix A Equipment and supplies
- Appendix B Common abbreviations and circuit symbols
- Appendix C RC circuits: frequency-domain analysis
- Appendix D Pinouts
- Glossary of basic electrical and electronic terms
- Index
8 - More op amp applications
Published online by Cambridge University Press: 06 July 2010
- Frontmatter
- Contents
- List of figures
- List of tables
- About the authors
- To the Reader
- Acknowledgments
- Introduction
- 1 Equipment familiarization: multimeter, breadboard, and oscilloscope
- 2 RC circuits
- 3 Diodes
- 4 Bipolar transistors
- 5 Transistors II: FETs
- 6 Transistors III: differential amplifier
- 7 Introduction to operational amplifiers
- 8 More op amp applications
- 9 Comparators and oscillators
- 10 Combinational logic
- 11 Flip-flops: saving a logic state
- 12 Monostables, counters, multiplexers, and RAM
- 13 Digital↔analog conversion
- Further reading
- Appendix A Equipment and supplies
- Appendix B Common abbreviations and circuit symbols
- Appendix C RC circuits: frequency-domain analysis
- Appendix D Pinouts
- Glossary of basic electrical and electronic terms
- Index
Summary
In Chapter 7 we studied some of the basic properties of operational amplifiers. There are an enormous number of ways that op amps can be applied to process analog signals. In this chapter we will explore several such applications: circuits that differentiate or integrate their input voltage as a function of time, form the logarithm or exponential of their input voltage, or rectify their input voltage. The op amp versions of these applications come closer to the ideal than the passive versions of some of them that you studied in earlier chapters. We will also see how to use feedback to compensate for the limitations of discrete devices.
Apparatus required
Breadboard, dual-trace oscilloscope with two attenuating probes, one 741C and one LF411 operational amplifier, one 1 k, two 10 k, and one 100 k 14 W resistor, 0.0047 μF and 0.033 μF capacitors, two 1N914 (or similar) silicon signal diodes, 2N3904 and 2N3906 transistors.
Op amp signal processing
Recall that for an inverting amplifier made from an op amp, with input resistor Ri and feedback resistor Rf, the gain is —Rf/Ri (neglecting the input offset voltage and offset and bias currents and taking the op amp open-loop gain to be infinite). We can generalize this result for devices other than resistors, as illustrated in Fig. 8.1.
- Type
- Chapter
- Information
- Hands-On ElectronicsA Practical Introduction to Analog and Digital Circuits, pp. 101 - 112Publisher: Cambridge University PressPrint publication year: 2003