Practical analog, digital, and embedded electronics for scientists / Brett D. DePaola.

Format:

Book

Author/Creator:

DePaola, Brett D. (Brett David), 1955- author.

Contributor:

Institute of Physics (Great Britain), publisher.

Series:

IOP ebooks. 2021 collection.

IOP ebooks. [2021 collection]

Language:

English

Subjects (All):

Electronics.

Physical Description:

1 online resource (various pagings) : illustrations (some color).

Place of Publication:

Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2020]

System Details:

Mode of access: World Wide Web.

System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.

Biography/History:

Brett DePaola is a Professor of Physics at Kansas State University. He received his BS and MS in Physics from Miami University, and his PhD in Physics from The University of Texas at Dallas. Professor DePaola's research in atomic, molecular, and optical physics covers a wide range of topics, from ion-atom collisions to coherent control using ultra-short laser pulses. The over-arching theme is the understanding of basic physical processes at the atomic level. His most recent research explores how modulating the spectral phase of ultra-short laser pulses affects coherent excitation in atoms and simple molecules. Professor DePaola has made seminal contributions to the measurement technique known as MOTRIMS, in which ultra-cold technologies are combined with charged particle technologies to create a powerful diagnostic of ion-atom and photon-atom dynamics. He is a Fellow of the American Physical Society and has won numerous teaching awards and given invited lectures world-wide. He has held Visiting Professor positions at universities in Denmark and Germany, spent time as a Visiting Scientist at RIKEN in Japan, and was a Visiting JILA Fellow in Boulder, Colorado.

Summary:

This book is different to other electronics texts available. First, it is short. Created for a one-semester course taken by physics students, both undergraduate and graduate it includes only the essentials and covers those topics only as deeply as needed in order to understand the material in the integrated laboratory exercises. Unlike many electronics texts for physics students, this one does not delve into the physics of devices. Instead, these are largely treated as black boxes having certain properties that are important to know for designing circuits. The physics comes when the students use their acquired electronics instrumentation knowledge to construct apparatus to make measurements. Since the detailed physics has been left out, this book should be equally useful for students in any of the physical or life sciences. This is the first textbook aimed at the non-electrical engineering student, that has both the generality on analog and digital electronics circuits, coupled to the very timely technology of embedded electronics. The book also features homework exercises, parts list and a suite of useful appendices.

Contents:

part I. Lectures. 1. Introduction

1.1. Laws of the land

1.2. The voltage divider (You can't believe how important this is!)

1.3. Mr Thévenin and his amazing equivalent circuit

1.4. Input and output impedances

1.5. Error propagation

2. RC circuits

2.1. R and C

2.2. RC filters

2.3. Doing calculus with R and C

3. Diodes and transistors

3.1. Signal diodes

3.2. Zener diodes

3.3. Bipolar junction transistors

4. Op amps I

4.1. Op amp basics

4.2. Examples

5. Op amps II : non-ideal behavior and positive feedback

5.1. Non-ideal behavior

5.2. Positive feedback

6. Digital gates : combinational and sequential logic

6.1. Counting in different bases

6.2. Binary arithmetic

6.3. Gates and truth tables

6.4. Combining outputs

6.5. Sequential logic

6.6. Counters

6.7. Latches

6.8. Monostable multivibrators

7. Digital-analog, analog-digital, and phase-locked loops

7.1. Digital-analog conversion

7.2. Analog-digital conversion

7.3. Phase-locked loops

7.4. Phase-sensitive detection (lock-in amplifiers)

8. Embedded electronics

8.1. Introduction

8.2. Inside the Beagle

8.3. The pins

8.4. Loading a DTO

8.5. Configuring the general purpose input/output pins

8.6. Pulse width modulation (PWM)

8.7. Buses

part II. Lab manual. 9. Getting started

9.1. Use of the lab manual

9.2. Maintaining a lab book

9.3. Use of general laboratory equipment

9.4. Play!

10. R and C

10.1. Low-pass filter

10.2. High-pass filter

10.3. Differentiator

10.4. Integrator

11. Transistors

11.1. Emitter follower

11.2. Input and output impedance of follower

11.3. Single-supply follower

11.4. Push-pull follower

11.5. Common emitter amplifier

11.6. Bypassed emitter amplifier

11.7. Current source (sink)

12. Op amps I

12.1. Open-loop test circuit

12.2. Inverting amplifier

12.3. Non-inverting amplifier

12.4. Follower

12.5. Current source

12.6. Summing amplifier

12.7. Push-pull follower

12.8. Integrator

12.9. Differentiator

12.10. Active rectifier

12.11. Improved active rectifier

12.12. Active clamp

13. Op amps II : positive feedback, good and bad

13.1. Comparators

13.2. The RC relaxation oscillator

13.3. RC relaxation oscillator using the 7555

13.4. Sine wave oscillator : Wien bridge

13.5. Op amp instability : phase shift can make an op amp oscillate

14. Digital gates : combinational and sequential logic

14.1. Gates and truth tables

14.2. Multiplexer

14.3. Sequential logic : JK flip-flop

14.4. Debouncing

14.5. D-type flip-flop

14.6. Programmable divide-by-N counter

15. Digital-analog, analog-digital, and phase-locked loops

15.1. Digital-analog conversion

15.2. Tracking analog-digital converter

15.3. Phase-locked loop : frequency multiplier

15.4. Phase sensitive detection : lock-in amplifiers (optional lab)

16. Embedded electronics, featuring the Beaglebone Black

16.1. Getting started

16.2. Input/output

16.3. Pulse width modulation (PWM)

16.4. Controlling the GPIO pins

16.5. Get on the bus!

part III. Solutions to homework. 17. RC circuits

18. Diodes and transistors

19. Op amps 1

20. Op-amps 2

21. Digital gates

22. Digital-analog, analog-digital and phase-locked loops

part IV. Appendices.

Notes:

"Version: 20201201"--Title page verso.

Includes bibliographical references.

Title from PDF title page (viewed on January 14, 2021).

ISBN:

0-7503-3490-8

0-7503-3491-6

OCLC:

1231597523