Students take advantage of the natural ability of red cabbage juice to perform as a pH indicator to test the pH of seven common household liquids. Then they evaluate the accuracy of the red cabbage indicator, by testing the pH of the liquids using an engineer-designed tool, pH indicator strips. Like environmental engineers working on water remediation or water treatment projects, understanding the chemical properties (including pH) of contaminants is important for safeguarding the health of environmental water sources and systems.

Building upon their understanding of forces and Newton's laws of motion, students learn about the force of friction, specifically with respect to cars. They explore the friction between tires and the road to learn how it affects the movement of cars while driving. In an associated literacy activity, students explore the theme of conflict in literature, and the difference between internal and external conflict, and various types of conflicts. Stories are used to discuss methods of managing and resolving conflict and interpersonal friction.

Students practice human-centered design by imagining, designing and prototyping a product to improve classroom accessibility for the visually impaired. To begin, they wear low-vision simulation goggles (or blindfolds) and walk with canes to navigate through a classroom in order to experience what it feels like to be visually impaired. Student teams follow the steps of the engineering design process to formulate their ideas, draw them by hand and using free, online Tinkercad software, and then 3D-print (or construct with foam core board and hot glue) a 1:20-scale model of the classroom that includes the product idea and selected furniture items. Teams use a morphological chart and an evaluation matrix to quantitatively compare and evaluate possible design solutions, narrowing their ideas into one final solution to pursue. To conclude, teams make posters that summarize their projects.

Deze cursus gaat over de representatie, analyse and regeling van lineare tijd-invariante dynamische systemen. Zowel de overdrachts functie als toestands modellen worden behandeld.

Veel aandacht zal worden gegeven aan het schetsen en interpreteren van bode, root-locus en nyquist plots voor de analyse van systeem stabiliteit en feedback regeling. In dit kader worden de concepten van versterking en fase marge, statische en dynamische compensatie behandeld. De verschillende compensatie methodes die onder de aandacht worden gebracht zijn: PD-compensatie, lead compensatie, PI compensatie, lag compensatie en PID compensatie.

Andere regel theoretische aspecten zoals sensitiviteits functies, robuustheid, tijdsvertraging, control en pool plaatsing van toestands beschrijvingen worden ook behandeld.

Students become familiar with the online Renewable Energy Living Lab interface and access its real-world solar energy data to evaluate the potential for solar generation in various U.S. locations. They become familiar with where the most common sources of renewable energy are distributed across the U.S. Through this activity, students and teachers gain familiarity with the living lab's GIS graphic interface and query functions, and are exposed to the available data in renewable energy databases, learning how to query to find specific information for specific purposes. The activity is intended as a "training" activity prior to conducting activities such as The Bright Idea activity, which includes a definitive and extensive end product (a feasibility plan) for students to create.

Students use real-world data to evaluate the feasibility of solar energy and other renewable energy sources in different U.S. locations. Working in small groups, students act as engineers evaluating the suitability of installing solar panels at four company locations. They access data from the online Renewable Energy Living Lab from which they make calculations and analyze how successful solar energy generation would be, as well as the potential for other power sources at those locations. Then they summarize their results, analysis and recommendations in the form of feasibility plans prepared for a CEO.

Students learn about how biomedical engineers aid doctors in repairing severely broken bones. They learn about using pins, plates, rods and screws to repair fractures. They do this by designing, creating and testing their own prototype devices to repair broken turkey bones.

It is expected that Students who take part in this course have completed almost all courses of their MSc and are about to start on their Master Orientation project, their Literature Study or MSc thesis depending on their chosen MSC track.

It is of little value to take this course early, so please plan accordingly!
Course Contents The aim of the course is to be a research-driven preparation for the aerospace engineering MSc thesis in the final year of the MSc. It will help you prepare for the challenges of your thesis work.

The course will consist of 7 lectures and will be taught online using video lectures in periods 1, 2 and 3 and face-to-face using traditional lectures in period 4.

The lecture set up is as follows:
1. Research Design in MSc - Introduction to research, research framework
2. Research Methods - Stages of a project, Research objective, research questions, research strategy, research methods
3. Data Analysis - Quantitative & Qualitative methods
4. Validation & Verification - How to validate & verify your work?
5. Project Management & Peer review of draft Project plan - How to manage your project and your thesis progress. Project plan peer review
6. Planning - How to plan, expectations, Gannt Charts
7. Literature Review - How to carry out a scientific literature review? Differences between review and research

Please be advised that all lectures are also available via Blackboard for those following the online version. It is possible to do this course by distant learning, attendance in the 4th period, though highly appreciated, is not mandatory!
Study Goals At the end of the course the student will:
- be aware of the expectations of an MSc student
- be able to formulate a research question and research aim
- be able to set up a research plan for their MOP/Literature Study/MSc thesis
- be able to write a literature review based on the research plan with a view to select appropriate methodologies for their MOP/MSc thesis

Education Method (Online) Lectures, Assignments and voluntary Peer review of each others research plans and literature studies

Innovation may bring a lot of good to society, but innovation is not a good in itself. History provides many examples of new technologies that have had serious negative consequences or that simply just failed to address significant societal challenges.

This course discusses the concept of responsible innovation, its meaning and its significance by addressing the societal implications of new technologies and showing how we might incorporate ethical considerations into technical innovations.

In this course, we will:
discuss the concept of responsible innovation, the individual and collective responsibility and the ethical issues regarding innovation
discuss tools and approaches to responsible innovation, like Value Sensitive Design (VSD)
investigate the economic aspects of responsible innovation
introduce constructive technology assessment
elucidate the relation between risk and responsible innovation
We will do so on the basis of technological case studies. Cases that will be discussed are, among others, nanotechnology, offshore wind parks, Google car, nuclear power, cloud computing, smart meters for electricity, robots in the care sector (carebots), low budget meteorological weather stations in Africa and CO2 capture and storage.

During the course you may team-up with your fellow students to discuss the case studies in an international context. Moreover, students are encouraged to bring their own cases in dedicated discussion fora.

This course is for all those interested in the relationship between technological innovations, ethics and society. It is especially relevant for industry, public, and academic professionals working on developing innovative technologies and students following a traditional technical curriculum who are interested in key value questions attached to their studies.

Responsible business practices are widely recognized as Corporate Social Responsibility (CSR). In this course we aim to extend these practices to the Research and Development (R&D) and innovation processes of companies. This is called Responsible Research and Innovation (RRI).

RRI enables companies to anticipate social and ethical issues and integrate them into the innovation and design processes and business strategy right from the start.

This course demonstrates how RRI, as a key element of CSR, can help firms to be innovative, more profitable and at the same time have positive societal and environmental impact.

In this course we analyze the relevance of RRI, including drivers and barriers, for firms of different sizes and in different sectors, and the implications for corporate governance. We show the results and lessons learned from eight pilot studies in innovative businesses across Europe working in different areas (such as nanotechnology, data and automotive) when they integrated RRI in their innovation process and business strategy.

This textbook is based on the MOOC Responsible Innovation offered by the TU Delft. It provides a framework to reflect on the ethics and risks of new technologies. How can we make sure that innovations do justice to social and ethical values? How can we minimize (unknown)risks?
The book explains:
•The concept and importance of responsible innovation for society
•Key ethical concepts and considerations to analyse the risks of new technologies
•Different types of innovation (e.g. radical, niche, incremental, frugal)
•Roadmap for Responsible Innovation by Industry
•The concept of Value Sensitive Design (VSD)
It includes a link to all the web lectures as well as case studies ranging from care robots and nuclear energy to Artificial Intelligence and self-driving vehicles.

The discovery of restriction enzymes and their applications in DNA analysis has proven to be essential for biologists and chemists. This lesson focuses on restriction enzymes and their applications to DNA analysis and DNA fingerprinting. Use this lesson and its associated activity in conjunction with biology lessons on DNA analysis and DNA replication.

You’ll learn about today’s urban challenges focusing on developing countries, referred to as the global south. We will debate the benefits of three pathways, going beyond traditional urban strategies and policies:

1. Spatial justice

Spatial justice is undoubtedly one of the greatest challenges of urban contexts in emerging economies.

2. Housing Provision and Management

Increasing demand in the global south calls for alternative approaches in housing provision and management.

3. Urban Resilience

Understanding resilience not as a mere struggle for survival, but as an opportunity to build better urban environments.

We will discuss question such as:

Is the just city framework applicable in cities with extreme socio-economic inequality?
Can community-led housing initiatives provide effective solutions for households in need?
How can resilience support development instead of perpetuating a disadvantaged condition?

Student pairs reverse engineer objects of their choice, learning what it takes to be an engineer. Groups each make a proposal, create a team work contract, use tools to disassemble a device, and sketch and document their full understanding of how it works. They compile what they learned into a manual and write-up that summarizes the object's purpose, bill of materials and operation procedure with orthographic and isometric sketches. Then they apply some of the steps of the engineering design process to come up with ideas for how the product or device could be improved for the benefit of the end user, manufacturer and/or environment. They describe and sketch their ideas for re-imagined designs (no prototyping or testing is done). To conclude, teams compile full reports and then recap their reverse engineering projects and investigation discoveries in brief class presentations. A PowerPoint(TM) presentation, written report and oral presentation rubrics, and peer evaluation form are provided.

Through this lesson students learn how AM radios work through basic concepts about waves and magnetic fields. Waves are first introduced by establishing the difference between transverse and longitudinal waves, as well as identifying the amplitude and frequency of a given waveform. Students then learn general concepts about magnetic fields, leading into how radio waves are created and transmitted. Several demonstrations can be performed in order to help students better understand these concepts. The goal of this lesson is for students to understand how the AM radios built during the associated activity function.

Students learn the concept of angular momentum and its correlation to mass, velocity and radius. They experiment with rotation and an object's mass distribution. In an associated literacy activity, students use basic methods of comparative mythology to consider why spinning and weaving are common motifs in creation myths and folktales.

11. Emerging Technologies: An Introduction to Cryptocurrency

The trifecta of globalization, urbanization and digitization have created new opportunities and challenges across our nation, cities, boroughs and urban centers. Cities are in a unique position at the center of commerce and technology becoming hubs for innovation and practical application of emerging technology. In this rapidly changing 24/7 digitized world, city governments worldwide are leveraging innovation and technology to become more effective, efficient, transparent and to be able to better plan for and anticipate the needs of its citizens, businesses and community organizations. This class will provide the framework for how cities and communities can become smarter and more accessible with technology and more connected.

The resource "Risk Assessment in Robotic Applications" is included in the Industrial Robotics topic of the EICC Engineering Techology Simulations resource series. This series is segment of a Department of Labor grant awarded to the Eastern Iowa Community Colleges (EICC) of Clinton, Muscatine, and Scott.

Students build on their understanding and feel for flow rates, as gained from the associated Faucet Flow Rate activity, to estimate the flow rate of a local river. The objective is to be able to relate laboratory experiment results to the environment. They use the U.S. Geological Survey website (http://waterdata.usgs.gov/nwis/rt) to determine the actual flow rate data for their river, and compare their estimates to the actual flow rate. For this activity to be successful, choose a nearby river and take a field trip or show a video so students gain a visual feel for the flow of the nearby river.

The resource "Robot construction" is included in the "Electrical engineering" course from Khan Academy. This resource is one of the sub-topics in the "Lego robotics" topic area.