This e-book is intended to be used as a complementary resource for engineering measurements and instrumentation courses, at a junior engineering level.
If you have any comments or suggestions, please reach out to the author via email: reza@iastate.edu

6.933J / STS.420J provides an integrated approach to engineering practice in the real world. Students of 6.933J / STS.420J research the life cycle of a major engineering project, new technology, or startup company from multiple perspectives: technical, economic, political, and cultural. Research involves interviewing inventors, reading laboratory notebooks, evaluating patents, and looking over the shoulders of engineers as they developed today's technologies. This subject is for students who recognize that technical proficiency alone is only part of the formula for success in technology.

The discipline of Biosystems Engineering emerged in the 1990s from the traditional strongholds of agricultural engineering and food engineering. Biosystems engineering integrates engineering science and design with applied biological, environmental, and agricultural sciences. Introduction to Biosystems Engineering is targeted at 1st and 2nd year university-level students with an interest in biosystems engineering but who are not yet familiar with the breadth and depth of the subject. It is designed as a coherent educational resource, also available for download as individual digital chapters. The book can be used as a localized, customizable text for introductory courses in Biosystems Engineering globally. It is written as a series of stand-alone chapters organized under six major topics: Food and Bioprocessing; Environment; Buildings and Infrastructure; Information and Communications Technology and Data; Machinery Systems; and Energy. Each chapter is organized around stated learning outcomes and describes key concepts, applications of the concepts, and worked examples.

By independent study of the book Sustainable Development for Engineers (K.F. Mulder, 2006) students acquire basic knowledge about sustainable development

Beginning kindergarteners are introduced to science and engineering concepts through questions such as “What is a Scientist?” and “What is an Engineer?”, and go on to compare and contrast the two. They are introduced to five steps of the engineering design process and explore these steps using the “I do, we do, you do” set of guided instruction. At the end of the project, students produce a set of purple popsicles that they design using various materials and by following a set of criteria.

This course introduces the theory and the practice of engineering ethics using a multi-disciplinary and cross-cultural approach. Theory includes ethics and philosophy of engineering. Historical cases are taken primarily from the scholarly literatures on engineering ethics, and hypothetical cases are written by students. Each student will write a story by selecting an ancestor or mythic hero as a substitute for a character in a historical case. Students will compare these cases and recommend action.

This course gives an overview of engineering management and covers topics such as financial principles, management of innovation, technology strategy, and best management practices. The focus of the course is the development of individual skills and team work. This is carried out through an exposure to management tools.

Instructional materials for the course "ENGR 1110: Engineering Graphics" include videos, assignments, slides, and drawings on the following topics: engineering graphics and scales, orthographic views, isometric views, dimensioning, section views, AutoCAD, layers, colors, mirrors, fillet, arrays, chamfer, blocks, Fusion 360, sheet metal modeling, tracing, textures, lofting and more.

Fundamentals of Aerospace Engineering covers an undergraduate, introductory course to aeronautical engineering and aims at combining theory and practice to provide a comprehensive, thorough introduction to the fascinating, yet complex discipline of aerospace engineering. This book is the ulterior result of three year of teaching a course called Aerospace Engineering in the first year of a degree in aerospace engineering (with a minor in air navigation) at the Universidad Rey Juan Carlos, in Madrid, Spain.

This unit of study introduces popular search engines and how to conduct 'efficient' searches.

- Participants are going to implement ICT resources in classroom and to learn about civil engineering, its types, some vocabulary, y know how important civil engineering is. - This lesson plan is going to be developed in two-hour class (Pre-activity 15 minutes; While 70 minutes; 15 minutes= 100 minutes)ICT FRAMEWORK FOR TEACHERS:- Critically engage with the need for ICT-led innovation and the transformative power of positive change.- Design and manage learning environments which take into account ICT in the didactics of a given subject area.- Awareness of the constant impact of ICT on learning. 

Engineering analysis distinguishes true engineering design from "tinkering." In this activity, students are guided through an example engineering analysis scenario for a scooter. Then they perform a similar analysis on the design solutions they brainstormed in the previous activity in this unit. At activity conclusion, students should be able to defend one most-promising possible solution to their design challenge. (Note: Conduct this activity in the context of a design project that students are working on; this activity is Step 4 in a series of six that guide students through the engineering design loop.)

Students in ESD.00 work on projects to address large, complex and seemingly intractable real-world problems, such as energy supply, environmental issues, health care delivery, and critical infrastructure (e.g., telecommunications, water supply, and transportation). The course introduces interdisciplinary approaches - rooted in engineering, management, and the social sciences - to considering these critical contemporary issues. Small, faculty-led teams select an engineering systems term project to illustrate one or more of these approaches.

Students learn about applied forces as they create pop-up-books the art of paper engineering. They also learn the basic steps of the engineering design process.

Students learn about the engineering design process and how it is used to engineer products for everyday use. Students individually brainstorm solutions for sorting coins and draw at least two design ideas. They work in small groups to combine ideas and build a coin sorter using common construction materials such as cardboard, tape, straws and fabric. Students test their coin sorters, make revisions and suggest ways to improve their designs. By designing, building, testing and improving coin sorters, students come to understand how the engineering design process is used to engineer products that benefit society.

Template of an Engineering Notebook that includes pages for:
- Table of Contents
- Design Brief
- Decision Matrix
- Graph Paper Pages

In this hands-on undergraduate class, students work in large teams of approximately 15-20 individuals to design and build working alpha prototypes of new products. The course is designed to emulate what engineers might experience as part of a design team in a modern product development firm. The large teams must work effectively to realize this task, so students also learn about group dynamics, team roles and management, consensus building, and the value of communication. 
Each year there is a broad theme which serves as a launching point for new product opportunities. At the end of the course, teams present their work to a live audience of ~1100 practicing product designers, entrepreneurs, academics, and classmates, as well as a significant live webcast audience—in the tens of thousands.
Key Goals:

To improve creative-thinking capability.
To improve ability to identify significant product opportunities, and to develop appropriate solutions through a structured product development process.
To improve expertise in constructing models for reasoning about design alternatives. These include estimations, sketches, sketch models, spreadsheets, geometric models, mockups, and prototypes.
To improve engineering expertise and proficiency in techniques for building high-quality product models and prototypes.
To learn about and experience structured methods for working in large teams on a project that requires teamwork to be successful.
To improve presentation skills using a wide variety of media.
To develop an understanding of, and enthusiasm for, the engineering activities involved with designing a new product.
To develop an appreciation for the significance of societal contributions that can be made as a technological innovator.

This course gives an introduction to probability and statistics, with emphasis on engineering applications. Course topics include events and their probability, the total probability and Bayes' theorems, discrete and continuous random variables and vectors, uncertainty propagation and conditional analysis. Second-moment representation of uncertainty, random sampling, estimation of distribution parameters (method of moments, maximum likelihood, Bayesian estimation), and simple and multiple linear regression. Concepts illustrated with examples from various areas of engineering and everyday life.

This site presents challenges faced by NASA engineers who are developing the next generation of aerospace vehicles. The challenges: thermal protection systems, spacecraft structures, electrodynamic propulsion systems, propellers, and personal satellite assistants. Students design, build, test, re-design, and re-build models that meet specified design criteria, using the same analytical skills as engineers.

This course studies the fundamentals of how the design and operation of internal combustion engines affect their performance, efficiency, fuel requirements, and environmental impact. Topics include fluid flow, thermodynamics, combustion, heat transfer and friction phenomena, and fuel properties, with reference to engine power, efficiency, and emissions. Students examine the design features and operating characteristics of different types of internal combustion engines: spark-ignition, diesel, stratified-charge, and mixed-cycle engines. The class includes lab project in the Engine Laboratory.