The standard laboratory tools in the modern scientific world include a wide variety of electronic instruments used in measurement and control systems. This book provides a firm foundation in principles, operation, design, and applications of electronic instruments. Commencing with electromechanical instruments, the specialized instruments such as signal analyzers, counters, signal generators, and digital storage oscilloscope are treated in detail. Good design practices such as grounding and shielding are emphasized. The standards in quality management, basics of testing, compatibility, calibration, traceability, metrology and various ISO 9000 quality assurance guidelines are explained as well. The evolution of communication technology in instrumentation is an important subject. A single chapter is devoted to the study of communication methods used in instrumentation technology. There are some areas where instrumentation needs special type of specifications-one such area is hazardous area. The technology and standards used in hazardous areas are also discussed. An instrumentation engineer is expected to draw and understand the instrumentation drawings. An Appendix explains the symbols and standards used in P&I diagrams with several examples. Besides worked-out examples included throughout, end-of-chapter questions and multiple choice questions are also given to judge the student's understanding of the subject. Practical and state-of-the-art in approach, this textbook will be useful for students of electrical, electronics, and instrumentation engineering.
This book covers principles of measurement, instruments, and instrumentation...a systems viewpoint, and covers the analysis of measurement problems associated with systems.
This text integrates engineering principles with real applications from a systems perspective, providing a framework for developing electronic instrumentation, from hand-held devices to consoles. It offers practical design solutions, describes the interactions, trade-offs, and priorities encountered and then gives specific examples. Written as a principle text for a senior design class, it also serves as a reference handbook for practicing engineers. While the focus is on projects often found in medium sized companies, many of the principles presented apply to larger companies as well.
Design and Development of Medical Electronic Instrumentation fills a gap in the existing medical electronic devices literature by providing background and examples of how medical instrumentation is actually designed and tested. The book includes practical examples and projects, including working schematics, ranging in difficulty from simple biopotential amplifiers to computer-controlled defibrillators. Covering every stage of the development process, the book provides complete coverage of the practical aspects of amplifying, processing, simulating and evoking biopotentials. In addition, two chapters address the issue of safety in the development of electronic medical devices, and providing valuable insider advice.
In recent years, Fundamentals of Electronic Measurement & Instrumentation are being used extensively in sensor, Electronics measurements and Instrumentation and signal processing research and many other things. This rapid progress in Electronic Measurement & Instrumentation has created an increasing demand for trained Electronics Engineering personnel. This book is intended for the undergraduate and postgraduate students specializing in Electronics Engineering. It will also serve as reference material for engineers employed in industry. The fundamental concepts and principles behind electronics engineering are explained in a simple, easy- to- understand manner. Each chapter contains a large number of solved example or problem which will help the students in problem solving and designing of Electronic Measurement & Instrumentation. This text book is organized into sixteen chapters. Chapter 1: Instrumentation, Measurement, Units & StandardsChapter 2: Errors in MeasurementChapter 3: Permanent Magnet Moving (PMMC) Coil InstrumentsChapter-4: Voltage and Current MeasurementChapter-5: Digital Measuring Instruments Chapter 6: Resistors and Measurement of ResistanceChapter 7: Measurement of Capacitance and Inductance Using AC BridgesChapter 8: Cathode Ray Oscilloscope and Digital Storage Oscilloscope Chapter- 9: Signal AnalyzerChapter- 10: Calibration, Display and Recording DevicesSalient Features*Detailed coverage of Instrumentation, Measurement, Units & Standards, Errors in Measurement, Permanent Magnet Moving (PMMC) Coil Instruments, Voltage and Current Measurement and Digital Measuring Instruments. *Detailed coverage of Resistors and Measurement of Resistance, Measurement of Capacitance and Inductance Using AC Bridges, Cathode Ray Oscilloscope and Digital Storage Oscilloscope, Signal Analyzer and Calibration, Display &Recording Devices*Each chapter contains a large number of solved example or objective type's problem which will help the students in problem solving and designing of Electronic Measurement & Instrumentation system. *Clear perception of the various problems with a large number of neat, well drawn and illustrative diagrams. *Simple Language, easy- to- understand manner. I do hope that the text book in the present form will meet the requirement of the students doing graduation in Electronics & Communication Engineering, Mechanical Engineering, Electronics & Instrumentation Engineering and Electrical & Electronics Engineering. I shall appreciate any suggestions from students and faculty members alike so that we can strive to make the text book more useful in the edition to come.
With the availability of advanced technologies, digital systems, and communications, portable instruments are rapidly evolving from simple, stand alone, low-accuracy measuring instruments to complex multifunctional, network integrated, high-performance digital devices with advanced interface capabilities. The relatively brief treatments these instr
This book was developed from material prepared for a course in instrumentation for final year mechanical engineering undergraduates. The approach used is to present instrumentation from the viewpoints of both electronics and signal analysis. The sensors and electronic circuits likely to be needed by a final year student project and for postgraduate research, are comprehensively covered. It forms a suitable degree-level text for students of engineering, science or medicine seeking a practical guide to instrumentation. It is also hoped that the book will be of use to practising engineers in general. The authors' aim throughout has been to write a book which guides the reader through the intricacies of specifying and selecting an instrumentation system, acquiring data without corrupting or distorting it in the process, and applying sensible signal analysis techniques. Examples and case studies are used to illustrate the techniques discussed, including many drawn from real-life instrumentation problems encountered by the authors in engineering, physics and medicine. The sequence of chapters follows the flow of data from the primary sensing element, through transduction, signal processing and digital conversion to digital signal analysis techniques. This logical sequence ensures that the design process is undertaken in the correct order, and provides continuity for the reader.
The second edition of Electronic Imaging in Astronomy: Detectors and Instrumentation describes the remarkable developments that have taken place in astronomical detectors and instrumentation in recent years – from the invention of the charge-coupled device (CCD) in 1970 to the current era of very large telescopes, such as the Keck 10-meter telescopes in Hawaii with their laser guide-star adaptive optics which rival the image quality of the Hubble Space Telescope. Authored by one of the world’s foremost experts on the design and development of electronic imaging systems for astronomy, this book has been written on several levels to appeal to a broad readership. Mathematical expositions are designed to encourage a wider audience, especially among the growing community of amateur astronomers with small telescopes with CCD cameras. The book can be used at the college level for an introductory course on modern astronomical detectors and instruments, and as a supplement for a practical or laboratory class.
