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OverviewHone your understanding of science and engineering concepts with the versatile Arduino microcontroller and powerful Raspberry Pi mini-computer. The simple, straightforward, fun projects in this book use the Arduino and Raspberry Pi to build systems that explore key scientific concepts and develop engineering skills. Areas explored include force/acceleration, heat transfer, light, and astronomy. You'll work with advanced tools, such as data logging, advanced design, manufacturing, and assembly techniques that will take you beyond practical application of the projects you'll be creating. Technology is ever evolving and changing. This book goes beyond simple how-tos to teach you the concepts behind these projects and sciences. You'll gain the skills to observe and adapt to changes in technology as you work through fun and easy projects that explore fundamental concepts of engineering and science. What You'll Learn Measure the acceleration of a car you're riding in Simulate zero gravity Calculate the heat transfer in and out of your house Photography the moon and planets Who This Book Is ForHobbyists, students, and instructors interested in practical applications and methods to measure and learn about the physical world using inexpensive Maker technologies. Full Product DetailsAuthor: Paul Bradt , David BradtPublisher: APress Imprint: APress Edition: 1st ed. Weight: 0.454kg ISBN: 9781484258101ISBN 10: 148425810 Pages: 238 Publication Date: 21 June 2020 Audience: Professional and scholarly , Professional & Vocational Format: Paperback Publisher's Status: Active Availability: Manufactured on demand  We will order this item for you from a manufactured on demand supplier. Table of Contents· Chapter 1: Introduction Provides a brief summary of the book and the goals. · Chapter 2: What is STEM This chapter will expand on the meaning of STEM and why each area is important. How it is good to understand the differences. The authors have found there is a bit of confusion and not many examples of good definitions. o Science: Expand knowledge o Technology: Tools and methods to use o Engineering: Solve problems and develop tools o Math: Communication tools to explain the world · Chapter 3: Arduino Basics This includes a short history of the Arduino and the basics of how to use it. · Chapter 4: Raspberry Pi Basics Short history of the Raspberry Pi and how it works. · Chapter 5: Data Logging Basics This section will demonstrate a couple of methods using the Arduino and Raspberry Pi for capturing and logging date. · Chapter 6: Math for Science and Engineering Concepts related to graphing and algebra will be covered in this section. Also the difference between weight, pressure, temperature and mass. · Chapter 7: Simple Projects This section explains several simple projects that can provide date on some basic physical properties. o Force: use of the force sensor. o Temperature: measuring temperature with two types of sensors. o Capturing counts: methods to capture counts of events. · Chapter 8: Math for Time and Other Dependent Functions This section will highlight some key math concepts such as time or condition dependency and how they can be used to analyze data and model or simulate system responses. · Chapter 9: Time/Condition Dependent Projects These projects gather data that may change based on time. The projects will show ways to measure and capture the data along with time stamps data. o Friction: Friction force can change between motion and the onset of motion. o Acceleration: sometimes acceleration is confused with velocity, but they are different. This project highlights that difference and a unique sensor to measure acceleration. o Zero gravity: Unique project that shows how the zero gravity simulator plane works. o Heat transfer: While we often measure temperature, heat transfer is really an important aspect, and this project shows how to measure it. · Chapter 10: Other Projects This section details additional interesting projects. o Astro photography: This section will show how to use a Raspberry Pi to capture beautiful images of the moon and several planets. o Light/radiation: One inexpensive sensor will be highlighted that can measure light intensity in different wave lengths like infrared or visible light. · Chapter 11: Conclusion · Chapter 12: References This section provides some additional information to aid the researcher to develop and build projects. o Design and decision: Design tools and decision methods will be discussed. o Safety concepts: Several safety related topics like safety glasses, filter masks and care around hot or sharp objects will be highlighted. o Drilling and tapping: Dos and don’ts related to drilling and tapping holes. o Soldering: Techniques of holding parts together for soldering. o 3D printing: Brief summary of some tools and techniques available now. Simulation techniques: Parabolic partial differential equations and other techniques.ReviewsAuthor InformationPaul Bradt has a BS in Computer Science from University of Houston Clear Lake. He currently runs a small company that provides IT support and works as a contractor developing various computer programs. He has worked extensively with microcomputers like Arduino and Pi and believes them to be excellent tools for developing an understanding of how electronic components and hardware interact in integrated systems. He also believes they are very useful as teaching aids in learning the basics of computer programming. Paul likes to promote STEM concepts through hands-on techniques. David Bradt has a BS in Mechanical Engineering from New Mexico State University with many years of experience in engineering, safety, reliability, industrial equipment, petrochemical and NASA. He likes using tools like the Raspberry Pi and the Arduino to capture data to help form the basis for informed analysis of the physical world. He enjoys building all kinds of systems and is an amateur astronomer. Tab Content 6Author Website:Countries AvailableAll regions |
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