Instead, it tells you-and shows you-what basic and advanced electronics parts and components do, and how they work. Chock-full of illustrations, Practical Electronics for Inventors offers over 750 hand-drawn images that provide clear, detailed instructions that can help turn theoretical ideas into real-life inventions and gadgets.

    Lavishly produced in full color, the book was quite unlike any commercially published radar book produced by the major technical publishers. The combination of clear, understandable writing and the unparalleled illustrations established the text-reference as a 'must-have' for engineers, technicians, pilots, and even sales and marketing people within the radar and aerospace industry. The book was authored by veteran Hughes engineer and Technical Manager George W. Stimson, a publications specialist. Individual chapters were thoroughly reviewed by the appropriate experts within the Hughes Radar Systems Group. The book was initially available 1983-1987 only to those within the Hughes family: employees and customers, primarily the military. Restriction was lifted in 1987. Hughes went through three printings and 40,000 copies 1983-1993, mostly by word-of-mouth testimonials and demand. Upon retirement from Hughes, George Stimson successfully negotiated for the rights to the book and made an agreement with SciTech Publishing to do a major revision of the text to update it. The resulting Second Edition has been overwhelmingly positive and a best-seller. Second Edition The revision is extensive: thirteen entirely new chapters cover the technological advances over the fifteen years since publication, two chapters considered obsolete have been deleted entirely, three chapters are extensively rewritten and updated, two chapters have been given new sections, and fourteen chapters have been given minor tweaks, corrections, and polishing. The book has grown from 32 chapters to 44 chapters in 584 efficiently-designed pages. Efforts have been made to bring more even-handed coverage to radars developed outside of Hughes Aircraft, while older and less important Hughes radars have been deleted or abbreviated. Chapter 44 catalogs many of the cutting edge radars in functioning aircraft and near-service aircraft in early stages of production. The book's appeal is to a diverse audience: from military pilots and radar officers eager to gain a sound technical understanding of the complex systems that their lives depend upon, on up through technicians, marketing, and sales people, to the radar system design specialists, who may 'know all that stuff' but who deeply admire the expression and thus use the book to teach others who have questions. The market encompasses companies directly involved in the radar business and those on the periphery, college professors of engineering and physics themselves, along with students in aviation, aeronautics, and electromagnetics and radar courses. The cross-disciplinary and multi-level demand for the book shows that the book should not be pigeon-holed as just a radar book for electrical engineers. Virtually anybody with a knowledge of high school algebra, trigonometry, and physics will be able to read and absorb most of the material.

    It gives an introduction to fundamental concepts and modern topics with applications to real-world problems. This is the first text in this area to fully integrate MATLAB and SIMULINK throughout. It also provides students with an author-developed POWER TOOLBOX DISK organized to perform analyses and explore power system design issues with ease.

    This is a thorough, up-to-date introduction to optimizing detection algorithms for implementation on digital computers. It focuses extensively on real-world signal processing applications, including state-of-the-art speech and communications technology as well as traditional sonar/radar systems. Start with a quick review of the fundamental issues associated with mathematical detection, as well as the most important probability density functions and their properties. Next, review Gaussian, Chi-Squared, F, Rayleigh, and Rician PDFs, quadratic forms of Gaussian random variables, asymptotic Gaussian PDFs, and Monte Carlo Performance Evaluations. Three chapters introduce the basics of detection based on simple hypothesis testing, including the Neyman-Pearson Theorem, handling irrelevant data, Bayes Risk, multiple hypothesis testing, and both deterministic and random signals. The author then presents exceptionally detailed coverage of composite hypothesis testing to accommodate unknown signal and noise parameters. These chapters will be especially useful for those building detectors that must work with real, physical data. Other topics covered include:Detection in nonGaussian noise, including nonGaussian noise characteristics, known deterministic signals, and deterministic signals with unknown parametersDetection of model changes, including maneuver detection and time-varying PSD detectionComplex extensions, vector generalization, and array processing The book makes extensive use of MATLAB, and program listings are included wherever appropriate. Designed for practicing electrical engineers, researchers, and advanced students, it is an ideal complement to Steven M. Kay's Fundamentals of Statistical Signal Processing, Vol. 1: Estimation Theory (Prentice Hall PTR, 1993, ISBN: 0-13-345711-7).

    This introductory book covers both discrete and continuous-time signal processing and uses practical examples form any fields to illustrate the theory. Advanced material, on topics like spectral analysis and filter design, and a practical emphasis mean that graduate students and professional engineers needing to upgrade their knowledge will also benefit from this book.

    Digital Systems Engineering presents a comprehensive treatment of these topics. It combines a rigorous development of the fundamental principles in each area with down-to-earth examples of circuits and methods that work in practice. The book not only can serve as an undergraduate textbook, filling the gap between circuit design and logic design, but also can help practicing digital designers keep up with the speed and power of modern integrated circuits. The techniques described in this book, which were once used only in supercomputers, are now essential to the correct and efficient operation of any type of digital system.

    This book includes plenty of real-world implementation guidance and just enough theory to keep you on the right track. The book's focus is on digital filtering and the use of the fast Fourier transform (FFT). By the end of the book, you'll feel comfortable specifying, designing, and implementing digital filters on both microcontrollers and other microprocessors. You'll also know how to use the FFT both as a standalone tool and as a shortcut for digital filtering. The book starts with the big picture, then covers continuous signals and systems; analog filters; digital signals and systems; FIR and IIR filters; frequency analysis, correlation, changing sampling rates, synthesis and much more. All examples use Motorola's 16-bit M68HC16 microcontroller, but they're applicable to a wide variety of processors, even modest 8-bit microcontrollers. For engineers who may not have a background in signal processing; technicians; embedded systems programmers, and students in electrical engineering or computer science.