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This practical book provides a complete, hands-on approach to understanding electronic devices and circuits, and includes many " real-world" schematics to help readers identify components, circuits, and circuit configurations covered in the text. Offers a complete survey of the field, covering everything from the fundamentals of solid-state principles to common diode applications, dc biasing circuits, amplifier operation, field-effect transistors, oscillators, switching voltage regulators, and more. Places many supportive features in the margins, including critical thinking questions, objective identifiers, notes highlighting the differences between theory and practice, a running glossary, reminders of previously studied material, and lab references. Integrates schematic and Electronic Workbench( applications problems throughout for additional circuit simulation experience. For professionals in the electronic technology field.
This new text by Denton J. Dailey covers both discrete and integrated components. Among the many features that students will find helpful in understanding the material are the following: Concept icons in the margins signify that topical coverage relates to other fields and areas of electronics, such as communications, microprocessors, and digital electronics. These icons help the reader to answer the question, "Why is it important for me to learn this?" Key terms presented in each chapter are defined in the margins to reinforce students' understanding. Chapter objectives introduce each chapter and provide students with a roadmap of topics to be covered.
Electronic Devices and Circuits, Volume 2 provides a comprehensive coverage of the concepts involved in electronic devices and circuitries. The text first details the network theory, and then proceeds to covering electronics in the succeeding chapters. The coverage of the book includes transmission lines; high-frequency valves and transistors; amplifiers; oscillators; and multivibrator and trigger circuits. The text also covers several concerns in electronics, such as the physics of semiconductor devices; stabilization of power supplies; and feedback. The book will be of great use to students of electrical engineering and other electronics related degree.
Jump start your journey with electronics! If you’ve thought about getting into electronics, but don’t know where to start, this book gives you the information you need. Starting with the basics of electricity and circuits, you'll be introduced to digital electronics and microcontrollers, capacitors and inductors, and amplification circuits – all while gaining the basic tools and information you need to start working with low-power electronics. Electronics for Beginners walks the fine line of focusing on projects-based learning, while still keeping electronics front and center. You'll learn the mathematics of circuits in an uncomplicated fashion and see how schematics map on to actual breadboards. Written for the absolute beginner, this book steers clear of being too math heavy, giving readers the key information they need to get started on their electronics journey. What You’ll Learn Review the basic “patterns” of resistor usage—pull up, pull down, voltage divider, and current limiter Understand the requirements for circuits and how they are put together Read and differentiate what various parts of the schematics do Decide what considerations to take when choosing components Use all battery-powered circuits, so projects are safe Who This Book Is For Makers, students, and beginners of any age interested in getting started with electronics.
Compact but comprehensive, this textbook presents the essential concepts of electronic circuit theory. As well as covering classical linear theory involving resistance, capacitance and inductance it treats practical nonlinear circuits containing components such as operational amplifiers, Zener diodes and exponential diodes. The book’s straightforward approach highlights the similarity between the equations describing direct current (DC), alternating current (AC) and small-signal nonlinear behaviour, thus making the analysis of these circuits easier to comprehend. Introductory Circuits explains: the laws and analysis of DC circuits including those containing controlled sources; AC circuits, focusing on complex currents and voltages, and with extension to frequency domain performance; opamp circuits, including their use in amplifiers and switches; change behaviour within circuits, whether intentional (small-signal performance) or caused by unwanted changes in components. In addition to worked examples within the text a number of problems for student solution are provided at the end of each chapter, ranging in difficulty from the simple to the more challenging. Most solutions for these problems are provided in the book, while others can be found on the accompanying website. Introductory Circuits is designed for first year undergraduate mechanical, biomedical, materials, chemical and civil engineering students who are taking short electrical engineering courses and find other texts on the subject too content-heavy for their needs. With its clear structure and consistent treatment of resistive, reactive and small-signal operation, this volume is also a great supporting text for mainstream electrical engineering students.
This new volume offers a broad view of the challenges of electronic devices and circuits for IoT applications. The book presents the basic concepts and fundamentals behind new low power, high-speed efficient devices, circuits, and systems in addition to CMOS. It provides an understanding of new materials to improve device performance with smaller dimensions and lower costs. It also looks at the new methodologies to enhance system performance and provides key parameters for exploring the devices and circuit performance based on smart applications. The chapters delve into myriad aspects of circuit design, including MOSFET structures depending on their low power applications for IoT-enabled systems, advanced sensor design and fabrication using MEMS, indirect bootstrap techniques, efficient CMOS comparators, various encryption-decryption algorithms, IoT video forensics applications, microstrip patch antennas in embedded IoT applications, real-time object detection using sound, IOT and nanotechnologies based wireless sensors, and much more.