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This book is evolved from the experience of the author who taught all lab courses in his three decades of teaching in various universities in India. The objective of this lab manual is to provide information to undergraduate students to practice experiments in electronics laboratories. This book covers 118 experiments for linear/analog integrated circuits lab, communication engineering lab, power electronics lab, microwave lab and optical communication lab. The experiments described in this book enable the students to learn: • Various analog integrated circuits and their functions • Analog and digital communication techniques • Power electronics circuits and their functions • Microwave equipment and components • Optical communication devices This book is intended for the B.Tech students of Electronics and Communication Engineering, Electrical and Electronics Engineering, Biomedical Electronics, Instrumentation and Control, Computer Science, and Applied Electronics. It is designed not only for engineering students, but can also be used by BSc/MSc (Physics) and Diploma students. KEY FEATURES • Contains aim, components and equipment required, theory, circuit diagram, pin-outs of active devices, design, tables, graphs, alternate circuits, and troubleshooting techniques for each experiment • Includes viva voce and examination questions with their answers • Provides exposure on various devices TARGET AUDIENCE • B.Tech (Electronics and Communication Engineering, Electrical and Electronics Engineering, Biomedical Electronics, Instrumentation and Control, Computer Science, and Applied Electronics) • BSc/MSc (Physics) • Diploma (Engineering)
This laboratory manual is carefully coordinated to the text Electronic Devices, Tenth edition, Global edition, by Thomas L. Floyd. The seventeen experiments correspond to the chapters in the text (except the first experiment references Chapters 1 and the first part of Chapter 2). All of the experiments are subdivided into two or three "Parts." With one exception (Experiment 12-B), the Parts for the all experiments are completely independent of each other. The instructor can assign any or all Parts of these experiments, and in any order. This format provides flexibility depending on the schedule, laboratory time available, and course objectives. In addition, experiments 12 through 16 provide two options for experiments. These five experiments are divided into two major sections identified as A or B. The A experiments continue with the format of previous experiments; they are constructed with discrete components on standard protoboards as used in most electronic teaching laboratories. The A experiments can be assigned in programs where traditional devices are emphasized. Each B experiment has a similar format to the corresponding A experiment, but uses a programmable Analog Signal Processor (ASP) that is controlled by (free) Computer Aided Design (CAD) software from the Anadigm company (www.anadigm.com). These experiments support the Programmable Analog Design feature in the textbook. The B experiments are also subdivided into independent Parts, but Experiment 12-B, Part 1, is a software tutorial and should be performed before any other B experiments. This is an excellent way to introduce the ASP technology because no other hardware is required other than a computer running the downloaded software. In addition to Experiment 12-B, the first 13 steps of Experiment 15-B, Part 2, are also tutorial in nature for the AnadigmFilter program. This is an amazing active filter design tool that is easy to learn and is included with the AnadigmDesigner2 (AD2) CAD software. The ASP is part of a Programmable Analog Module (PAM) circuit board from the Servenger company (www.servenger.com) that interfaces to a personal computer. The PAM is controlled by the AD2 CAD software from the Anadigm company website. Except for Experiment 12-B, Part 1, it is assumed that the PAM is connected to the PC and AnadigmDesigner2 is running. Experiment 16-B, Part 3, also requires a spreadsheet program such as Microsoft® Excel®. The PAM is described in detail in the Quick Start Guide (Appendix B). Instructors may choose to mix A and B experiments with no loss in continuity, depending on course objectives and time. We recommend that Experiment 12-B,Part 1, be assigned if you want students to have an introduction to the ASP without requiring a hardware purchase. A text feature is the Device Application (DA) at the end of most chapters. All of the DAs have a related laboratory exercise using a similar circuit that is sometimes simplified to make laboratory time as efficient as possible. The same text icon identifies the related DA exercise in the lab manual. One issue is the trend of industry to smaller surface-mount devices, which are very difficult to work with and are not practical for most lab work. For example, almost all varactors are supplied as surface mount devices now. In reviewing each experiment, we have found components that can illustrate the device function with a traditional one. The traditional through-hole MV2109 varactor is listed as obsolete, but will be available for the foreseeable future from Electronix Express (www.elexp.com), so it is called out in Experiment 3. All components are available from Electronix Express (www.elexp.com) as a kit of parts (see list in Appendix A). The format for each experiment has not changed from the last edition and is as follows: · Introduction: A brief discussion about the experiment and comments about each of the independent Parts that follow. · Reading: Reading assignment in the Floyd text related to the experiment. · Key Objectives: A statement specific to each Part of the experiment of what the student should be able to do. · Components Needed: A list components and small items required for each Part but not including the equipment found at a typical lab station. Particular care has been exercised to select materials that are readily available and reusable, keeping cost at a minimum. · Parts: There are two or three independent parts to each experiment. Needed tables, graphs, and figures are positioned close to the first referenced location to avoid confusion. Step numbering starts fresh with each Part, but figures and tables are numbered sequentially for the entire experiment to avoid multiple figures with the same number. § Conclusion: At the end of each Part, space is provided for a written conclusion. § Questions: Each Part includes several questions that require the student to draw upon the laboratory work and check his or her understanding of the concepts. Troubleshooting questions are frequently presented. · Multisim Simulation: At the end of each A experiment (except #1), one or more circuits are simulated in a Multisim computer simulation. New Multisim troubleshooting problems have been added to this edition. Multisim troubleshooting files are identified with the suffix f1, f2, etc., in the file name (standing for fault1, fault2, etc.). Other files, with nf as the suffix include demonstrations or practice using instruments such as the Bode Plotter and the Spectrum Analyzer. A special icon is shown with all figures that are related to the Multisim simulation. Multisim files are found on the website: www.pearsonglobaledition.com/Floyd. Microsoft PowerPoint® slides are available at no cost to instructors for all experiments. The slides reinforce the experiments with troubleshooting questions and a related problem and are available on the instructor''s resource site. Each laboratory station should contain a dual-variable regulated power supply, a function generator, a multimeter, and a dual-channel oscilloscope. A list of all required materials is given in Appendix A along with information on acquiring the PAM. As mentioned, components are also available as a kit from Electronix Express; the kit number is 32DBEDFL10.
The emphasis is first on understanding the characteristics of basic circuits including resistors, capacitors, diodes, and bipolar and field effect transistors. The readers then use this understanding to construct more complex circuits such as power supplies, differential amplifiers, tuned circuit amplifiers, a transistor curve tracer, and a digital voltmeter. In addition, readers are exposed to special topics of current interest, such as the propagation and detection of signals through fiber optics, the use of Van der Pauw patterns for precise linewidth measurements, and high gain amplifiers based on active loads. KEY TOPICS: Chapter topics include Thevenin's Theorem; Resistive Voltage Division; Silicon Diodes; Resistor Capacitor Circuits; Half Wave Rectifiers; DC Power Supplies; Diode Applications; Bipolar Transistors; Field Effect Transistors; Characterization of Op-Amp Circuits; Transistor Curve Tracer; Introduction to PSPICE and AC Voltage Dividers; Characterization and Design of Emitter and Source Followers; Characterization and Design of an AC Variable Gain Amplifier; Design of Test Circuits for BJT's and FET's and Design of FET Ring Oscillators; Design and Characterization of Emitter Coupled Transistor Pairs; Tuned Amplifier and Oscillator; Design of Am Radio Frequency Transmitter and Receiver; Design of Oscillators Using Op-Amps; Current Mirrors and Active Loads; Sheet Resistance; Design of Analog Fiber Optic Transmission System; Digital Voltmeter.
This book is primarily designed to serve as a textbook for undergraduate students of electrical, electronics, and computer engineering, but can also be used for primer courses across other disciplines of engineering and related sciences. The book covers all the basic aspects of electronics engineering, from electronic materials to devices, and then to basic electronic circuits. The book can be used for freshman (first year) and sophomore (second year) courses in undergraduate engineering. It can also be used as a supplement or primer for more advanced courses in electronic circuit design. The book uses a simple narrative style, thus simplifying both classroom use and self study. Numerical values of dimensions of the devices, as well as of data in figures and graphs have been provided to give a real world feel to the device parameters. It includes a large number of numerical problems and solved examples, to enable students to practice. A laboratory manual is included as a supplement with the textbook material for practicals related to the coursework. The contents of this book will be useful also for students and enthusiasts interested in learning about basic electronics without the benefit of formal coursework.
Well-written, handy and comprehensive, this laboratory experiments manual caters to the requirements of students of Electronics and Communication Engineering. Each experiment in the book provides essential theory, aim, scope, statement, equipment required, procedure, complete circuit diagram, tabulation, model graphs and results. A complete laboratory manual for students of electronics and communication engineering. Also useful for EEE, EIE, CSE, IT, ICE mechanical and polytechnic students.
This junior level electronics text provides a foundation for analyzing and designing analog and digital electronics throughout the book. Extensive pedagogical features including numerous design examples, problem solving technique sections, Test Your Understanding questions, and chapter checkpoints lend to this classic text. The author, Don Neamen, has many years experience as an Engineering Educator. His experience shines through each chapter of the book, rich with realistic examples and practical rules of thumb.The Third Edition continues to offer the same hallmark features that made the previous editions such a success.Extensive Pedagogy: A short introduction at the beginning of each chapter links the new chapter to the material presented in previous chapters. The objectives of the chapter are then presented in the Preview section and then are listed in bullet form for easy reference.Test Your Understanding Exercise Problems with provided answers have all been updated. Design Applications are included at the end of chapters. A specific electronic design related to that chapter is presented. The various stages in the design of an electronic thermometer are explained throughout the text.Specific Design Problems and Examples are highlighted throughout as well.