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This introduction to the field of electrical engineering includes an explanation of electricity and currents, as well as chapters devoted to specific areas. An activity that demonstrates how circuits work helps young readers get a hands-on chance to learn about electrical engineering.
This book addresses the job of civil engineers and explains how some of the world's greatest engineering marvels were built. Students will learn how tunnels such as the English Channel Tunnel are built under water; how dams like the Hoover Dam are built and the purpose they serve a community; and why the Panama Canal was an important improvement to world trade.
Mathematics for Electrical Engineering and Computing embraces many applications of modern mathematics, such as Boolean Algebra and Sets and Functions, and also teaches both discrete and continuous systems - particularly vital for Digital Signal Processing (DSP). In addition, as most modern engineers are required to study software, material suitable for Software Engineering - set theory, predicate and prepositional calculus, language and graph theory - is fully integrated into the book.Excessive technical detail and language are avoided, recognising that the real requirement for practising engineers is the need to understand the applications of mathematics in everyday engineering contexts. Emphasis is given to an appreciation of the fundamental concepts behind the mathematics, for problem solving and undertaking critical analysis of results, whether using a calculator or a computer.The text is backed up by numerous exercises and worked examples throughout, firmly rooted in engineering practice, ensuring that all mathematical theory introduced is directly relevant to real-world engineering. The book includes introductions to advanced topics such as Fourier analysis, vector calculus and random processes, also making this a suitable introductory text for second year undergraduates of electrical, electronic and computer engineering, undertaking engineering mathematics courses.Dr Attenborough is a former Senior Lecturer in the School of Electrical, Electronic and Information Engineering at South Bank University. She is currently Technical Director of The Webbery - Internet development company, Co. Donegal, Ireland. - Fundamental principles of mathematics introduced and applied in engineering practice, reinforced through over 300 examples directly relevant to real-world engineering
This book is an invaluable resource for applied researchers to find the analytical solution of differential equations describing the dynamical system with less computational effort and time. It describes the basic concepts of the differential transform method and solution of various real-world problems described by simple to complicated differential equations. It provides a computational technique that is not only conceptually simple and easy to use but also readily adaptable for computer coding. Different chapters of the book deal with the basic differential equations involved in the physical phenomena as well as a complicated system of differential equations described by the mathematical model. The book offers comprehensive coverage of the most essential topics, including Basic concepts and fundamental properties of the proposed technique with proof The solution of linear, nonlinear, homogeneous, and nonhomogeneous ordinary differential equations (ODEs) and partial differential equations (PDEs) The initial and boundary value problems Real-world ODE and PDE problems are also discussed Applications of Differential Transform to Real World Problems is primarily aimed at undergraduates, graduates, and researchers studying differential equations. Scientists dealing with complicated differential equations or systems of differential equations will also find this book useful.
A step-by-step guide for electrical engineering students.
Electrical Engineering 101 covers the basic theory and practice of electronics, starting by answering the question "What is electricity?" It goes on to explain the fundamental principles and components, relating them constantly to real-world examples. Sections on tools and troubleshooting give engineers deeper understanding and the know-how to create and maintain their own electronic design projects. Unlike other books that simply describe electronics and provide step-by-step build instructions, EE101 delves into how and why electricity and electronics work, giving the reader the tools to take their electronics education to the next level. It is written in a down-to-earth style and explains jargon, technical terms and schematics as they arise. The author builds a genuine understanding of the fundamentals and shows how they can be applied to a range of engineering problems. This third edition includes more real-world examples and a glossary of formulae. It contains new coverage of: - Microcontrollers - FPGAs - Classes of components - Memory (RAM, ROM, etc.) - Surface mount - High speed design - Board layout - Advanced digital electronics (e.g. processors) - Transistor circuits and circuit design - Op-amp and logic circuits - Use of test equipment - Gives readers a simple explanation of complex concepts, in terms they can understand and relate to everyday life. - Updated content throughout and new material on the latest technological advances. - Provides readers with an invaluable set of tools and references that they can use in their everyday work.
Electrical engineering is a field of engineering that encompasses the study, design, and application of devices, systems, and equipment that use electricity, electronics, and electromagnetism. Since its inception in the late 19th century, following the commercialization of the electric telegraph and electrical power supply, electrical engineering has grown exponentially, impacting nearly every aspect of modern life. The field of electrical engineering is broad, covering a range of sub-disciplines such as power engineering, control systems, electronics, microelectronics, signal processing, telecommunications, and instrumentation. Each sub-discipline focuses on specific technologies and applications, from the generation and distribution of electrical power to the design of complex electronic circuits and communication systems. Historical Perspective The roots of electrical engineering can be traced back to pioneering scientists and inventors such as Michael Faraday, Nikola Tesla, and Thomas Edison. Their foundational work laid the groundwork for the development of electric power and telecommunications systems, fundamentally transforming society and setting the stage for future advancements. Core Areas and Applications Power Engineering: This area focuses on the generation, transmission, distribution, and utilization of electrical power. Engineers in this field design systems for power plants, electrical grids, and renewable energy sources, ensuring efficient and reliable electricity supply. Control Systems: Control engineering deals with the design and implementation of controllers that manage dynamic systems. Applications range from industrial automation to the stabilization of aircraft and spacecraft. Electronics and Microelectronics: Electronics engineering involves the design of electronic circuits, devices, and systems. Microelectronics, a subfield, delves into the fabrication of tiny electronic components used in integrated circuits, which are essential for modern computing and communication technologies. Signal Processing: This area focuses on the analysis and manipulation of signals, which can be analog or digital. Signal processing is crucial for applications in communications, audio and video technology, and medical imaging. Telecommunications: Telecommunications engineering involves the transmission of information across channels such as cables, optical fibers, or airwaves. This sub-discipline is vital for internet, telephone, and satellite communications. Instrumentation: Instrumentation engineering centers on the design and development of devices that measure and control physical quantities. This includes everything from simple thermometers to complex automated systems used in manufacturing and research. Future Directions Electrical engineering continues to evolve rapidly, driven by technological advancements and societal needs. Emerging areas such as renewable energy, smart grids, nanotechnology, and artificial intelligence present new challenges and opportunities for innovation. The integration of interdisciplinary knowledge from computer science, material science, and biology is also expanding the scope and impact of electrical engineering. As we look to the future, electrical engineers will play a pivotal role in addressing global challenges such as sustainable energy, efficient resource management, and advanced communication networks. Their expertise will be crucial in developing innovative solutions that enhance the quality of life and drive economic progress. Conclusion The field of electrical engineering is dynamic and ever-changing, with a rich history and a promising future. Its principles and applications are foundational to the technological advancements that shape our modern world. Aspiring electrical engineers are entering a profession that not only demands technical proficiency and creativity but also offers the opportunity to make significant contributions to society. This preface provides an overview of electrical engineering, highlighting its history, core areas, and future prospects, setting the stage for a deeper exploration of the subject.
Education is expanding to include a stronger focus on the practical application of classroom lessons in an effort to prepare the next generation of scholars for a changing world economy centered on collaborative and problem-solving skills for the digital age. The Handbook of Research on Technology Tools for Real-World Skill Development presents comprehensive research and discussions on the importance of practical education focused on digital literacy and the problem-solving skills necessary in everyday life. Featuring timely, research-based chapters exploring the broad scope of digital and computer-based learning strategies including, but not limited to, enhanced classroom experiences, assessment programs, and problem-solving training, this publication is an essential reference source for academicians, researchers, professionals, and policymakers interested in the practical application of technology-based learning for next-generation education.