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The purpose of this book is to provide an in-depth information on fundamentals of Engineering Physics to the student community to improve their general understanding on the subject. The book has been designed as a textbook for the beginners in all branches of Engineering according to the latest syllabus.
This is one of enumerable self-help or how to books with an emphasis on Engineering Physics Practical. The basic premise of the book is that there are certain simple experiments, involving no more than rudimentary Physics laws and the very basic laws of Engineering Physics for undergraduate college engineering students. But these practical are often not done or taken lightly, for several reasons. First, people don’t realize how easy they are to do. Second, and more fundamental, they are not done because it does not occur to people to do them. Finally, and tragically, no one in their elementary, middle, or high school educational experience has stressed the importance of doing them, and of course neither did they teach to do them. This book is to reveal to you what the experiments are, make them readily understandable, and by means of a very easy-to-use illustrations. The main thing you should expect from this book is the theories and practical related small information more precisely about experiments. You will get a rudimentary understanding of the basic concepts behind the Engineering Physics experiment that governs the fundamental daily life questions that challenge us in life. The book is divided into seven major categories and Fifteen chapters. In this book the students will find solutions to experimental obstacles normally faced by undergraduate college engineering students. students. In summary, you don’t need any special background or ability to profit from this book.
Introduction * Torsional Pendulum * Compound Pendulum * Laser Grating Determination Of Wavelength * Optical Fibres-Measurement Of Numerical Aperture * Optical Fibres * Attenuation In Fibres * Spectrometer-Refractive Index Of Prism * Spectrometer * I-D Curve O Air Wedged * Hysterisis-Energy Loss Of Ferrites * B.H. Curve-Energy Loss Of Ferrites (Display Of B.H. Curve On Cro Screen) * Magnetic Susceptibility-Quincke'S Method * Band Gap Energy Of A Semiconductor * Semiconductor Diode Characteristics * Compressibility Of Liquid-Ultrasonic Interferometer * Excess Adiabatic Compressibility Of A Binary * Mixture-Ultrasonic Interferometer * Magnetic Susceptibility-Quincke'S Method (Alternative Approach) * Magnetic Susceptibility-Guoy'S Method.
The present book is designed for the first year engineering students.
The market leader for the first-year physics laboratory course, this manual offers a wide range of class-tested experiments designed explicitly for use in small to mid-size lab programs. The manual provides a series of integrated experiments that emphasize the use of computerized instrumentation. The Sixth Edition includes a set of "computer-assisted experiments" that allow students and instructors to use this modern equipment. This option also allows instructors to find the appropriate balance between traditional and computer-based experiments for their courses. By analyzing data through two different methods, students gain a greater understanding of the concepts behind the experiments. The manual includes 14 new integrated experiments—computerized and traditional—that can also be used independently of one another. Ten of these integrated experiments are included in the standard (bound) edition; four are available for customization. Instructors may elect to customize the manual to include only those experiments they want. The bound volume includes the 33 most commonly used experiments that have appeared in previous editions; an additional 16 experiments are available for examination online. Instructors may choose any of these experiments—49 in all—to produce a manual that explicitly matches their course needs. Each experiment includes six components that aid students in their analysis and interpretation: Advance Study Assignment, Introduction and Objectives, Equipment Needed, Theory, Experimental Procedures, and Laboratory Report and Questions.
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 is a textbook for upper undergraduate and graduate courses on microwave engineering, written in a student-friendly manner with many diagrams and illustrations. It works towards developing a foundation for further study and research in the field. The book begins with a brief history of microwaves and introduction to core concepts of EM waves and wave guides. It covers equipment and concepts involved in the study and measurement of microwaves. The book also discuses microwave propagation in space, microwave antennae, and all aspects of RADAR. The book provides core pedagogy with chapter objectives, summaries, solved examples, and end-of-chapter exercises. The book also includes a bonus chapter which serves as a lab manual with 15 simple experiments detailed with proper circuits, precautions, sample readings, and quiz/viva questions for each experiment. This book will be useful to instructors and students alike.
Lab Manual for Biomedical Engineering: Devices and Systems examines key concepts in biomedical systems and signals in a laboratory setting. The book gives students the opportunity to complete both measurement and math modeling exercises, thus demonstrating that the experimental real-world setting directly corresponds with classroom theory. All the experiments in the lab manual have been extensively class-tested and cover concepts such as wave math, Fourier transformation, electronic and random noise, transfer functions, and systems modeling. Each experiment builds on knowledge acquired in previous experiments, allowing the level of difficulty to increase at an appropriate pace. In completing the lab work, students enhance their understanding of the lecture course. The third edition features expanded exercises, additional sample data and measurements, and lab modifications for increased ease and simple adaptation to the online teaching and learning environment. Individual activities have also been added to aid with independent learning. Lab Manual for Biomedical Engineering is ideal for undergraduate courses in biomedical engineering comprised of students who have completed introductory electrical and mechanical physics courses. A two-semester background in calculus is recommended.
Biophotonics is a burgeoning field that has afforded researchers and medical practitioners alike an invaluable tool for implementing optical microscopy. Recent advances in research have enabled scientists to measure and visualize the structural composition of cells and tissue while generating applications that aid in the detection of diseases such as cancer, Alzheimer’s, and atherosclerosis. Rather than divulge a perfunctory glance into the field of biophotonics, this textbook aims to fully immerse senior undergraduates, graduates, and research professionals in the fundamental knowledge necessary for acquiring a more advanced awareness of concepts and pushing the field beyond its current boundaries. The authors furnish readers with a pragmatic, quantitative, and systematic view of biophotonics, engaging such topics as light-tissue interaction, the use of optical instrumentation, and formulating new methods for performing analysis. Designed for use in classroom lectures, seminars, or professional laboratories, the inclusion and incorporation of this textbook can greatly benefit readers as it serves as a comprehensive introduction to current optical techniques used in biomedical applications. Caters to the needs of graduate and undergraduate students as well as R&D professionals engaged in biophotonics research. Guides readers in the field of biophotonics, beginning with basic concepts before proceeding to more advanced topics and applications. Serves as a primary text for attaining an in-depth, systematic view of principles and applications related to biophotonics. Presents a quantitative overview of the fundamentals of biophotonic technologies. Equips readers to apply fundamentals to practical aspects of biophotonics.
This textbook provides the knowledge and skills needed for thorough understanding of the most important methods and ways of thinking in experimental physics. The reader learns to design, assemble, and debug apparatus, to use it to take meaningful data, and to think carefully about the story told by the data. Key Features: Efficiently helps students grow into independent experimentalists through a combination of structured yet thought-provoking and challenging exercises, student-designed experiments, and guided but open-ended exploration. Provides solid coverage of fundamental background information, explained clearly for undergraduates, such as ground loops, optical alignment techniques, scientific communication, and data acquisition using LabVIEW, Python, or Arduino. Features carefully designed lab experiences to teach fundamentals, including analog electronics and low noise measurements, digital electronics, microcontrollers, FPGAs, computer interfacing, optics, vacuum techniques, and particle detection methods. Offers a broad range of advanced experiments for each major area of physics, from condensed matter to particle physics. Also provides clear guidance for student development of projects not included here. Provides a detailed Instructor’s Manual for every lab, so that the instructor can confidently teach labs outside their own research area.