If you’re interested in the concept of building with nature, then this is the engineering course for you. This course explores the use of natural materials and ecological processes in achieving effective and sustainable hydraulic infrastructural designs. You will learn the Building with Nature ecosystem-based design concept and its applications in water and coastal systems. During the course, you will be presented with a range of case studies to deepen your knowledge of ecological and engineering principles.

You’ll learn from leading Dutch engineers and environmental scientists who see the Building with Nature integrated design approach as fundamental to a new generation of engineers and ecologists.

Products and equipment all around us are made of materials: look around you and you will see phones, computers, cars, and buildings. We face challenges in securing the supply of materials and the impact this has on the planet. Innovative product design can help us find solutions to these challenges. This course will explore new ways of designing products.

The design of products is an important aspect of a circular economy. The circular economy approach addresses material supply challenges by keeping materials in use much longer and eventually returning materials for new use. The principle is that waste must be minimized. Products will be designed to last longer. They will be easier to Reuse, Repair, and Remanufacture. The product will eventually be broken down and Recycled. This is Design for R and is the focus of this course.

Experts from leading European universities and research organizations will explain the latest strategies in product design. Current design approaches lead to waste, loss of value and loss of resources. You will learn about the innovative ways in which companies are creating value, whilst securing their supply chains, by integrating Design for R.

This course is suitable for all learners who have an interest in product design, innovative engineering, new business activity, entrepreneurship, sustainability, circular economy and everyone who thinks that the current way we do things today needs a radical rethink.

This course covers the major topics of mechanics, including momentum and energy conservation, kinematics, Newton‰ŰŞs laws and equilibrium. The major emphasis is to develop critical analysis, problem solving and scientific reasoning skills by considering numerous different systems and interactions, solving problems and discussion. It uses a systematic approach based on modeling systems by application of basic physics principles, making assumptions, utilizing multiple representations (not just mathematical) in order to become proficient at problem solving. Lab work is required and is designed to help students develop a questioning approach to physical situations, distinguishing the significant behaviors from the less significant behaviors of a system under study.Login: guest_oclPassword: ocl

This is an expository writing course requiring more advanced writing skills than Basic English Composition 101, yet reviewing and incorporating some of the same skills. This course teaches you research skills by emphasizing the development of advanced analytical/critical reading skills, proficiency in investigative research, and the writing of expository and persuasive prose including properly documented and researched argumentative essays. A major component of this course will be an emphasis on the research process or ‰ŰĎinformation literacy‰Ű: your ability to locate, evaluate and use information effectively. You also will recognize academic audiences, increase your clarity and objectivity, and adhere to standard formats.Login: guest_oclPassword: ocl

Are you an entrepreneur, or do you have a passion for building your own technology startup? This course will help and encourage you to start a successful technology-based venture.

If you always wanted to become an entrepreneur, or if you are simply interested in putting a new technology to innovative use, this course is for you.

This course helps you understand the process of entrepreneurship from a technology-oriented background.

The course is made up of modules that are presented by experts in the field of entrepreneurship and technology. Modules include:

Team Building
Opportunity Recognition
Financing
Customer Acquisition

This course will introduce you to entrepreneurship for global challenges in emerging markets. You will get to know other like-minded entrepreneurs around you, and discover how institutions in your target region are working on innovation and entrepreneurship.

As an entrepreneur in an emerging market, you may be faced with many challenges that need to be solved. These might include scarcity of fossil fuels, climate change or water, food and health security. This Delft University of Technology course will provide you with examples from partner universities and affiliated entrepreneurs in emerging markets which explain the opportunities and obstacles that they faced as they established themselves and created value.

You will acquire a set of practical tools which will enable you to discover the opportunities in your own environment and how these can be used to make an actual change! You will learn how to rethink your value proposition with your own case study, or with one we provide.

After the course, you will be able to develop your value proposition more quickly by getting to know your customers and partners better and understand local values and institutions.

Increasingly volatile climate and weather; vulnerable drinking water supplies; shrinking wildlife habitats; widespread deforestation due to energy and food production. These are examples of environmental challenges that are of critical importance in our world, both in far away places and close to home, and are particularly well suited to inquiry using geographic information systems. In GEOG 487 you will explore topics like these and learn about data and spatial analysis techniques commonly employed in environmental applications. After taking this course you will be equipped with relevant analytical approaches and tools that you can readily apply to your own environmental contexts.

Students are introduced to the fundamentals of environmental engineering as well as the global air, land and water quality concerns facing today's environmental engineers. After a lesson and activity to introduce environmental engineering, students learn more about water chemistry aspects of environmental engineering. Specifically, they focus on groundwater contamination and remediation, including sources of contamination, adverse health effects of contaminated drinking water, and current and new remediation techniques. Several lab activities provide hands-on experiences with topics relevant to environmental engineering concerns and technologies, including removal efficiencies of activated carbon in water filtration, measuring pH, chromatography as a physical separation method, density and miscibility.

The year is 2050 and your once-idyllic beachfront vacation home is now flooded up to the second story. The crab your family has enjoyed every Christmas for as long as you can remember has now become an endangered species. The oceans have changed. In Earth 540, Oceanography for Educators, we explore the mechanisms that lead to sea level rise and ocean acidification. We strive to understand how natural processes such as ocean currents, the gulf-stream, tides, plate tectonics, and the Coriolis Effect, affect our oceans and ocean basins. We then predict how man-made issues such as climate change and overfishing will affect our beloved waters and our livelihoods. Want to see into the future? Then this course is for you!

This course presents an examination of ethical issues relevant to systems-based research procedures, professional conduct, social and environmental impacts, and embedded ethics in research and professional practice in RESS based jobs. In this course, you will consider case studies of ethical issues that can arise when engaging renewable energy and sustainability systems. You will also develop an ethics case study based on your area of RESS interests. The goals of the course are to provide you with tools for analyzing ethical issues both in the line of professional duties and in consideration of the various ethical issues that face an entire sector of renewable energy and that underpin the very reasons for taking a sustainable and renewable approach.

The following set of materials is used in the Textbook Transformation Grants implementation of Ethical Hacking for Effective Defense:

https://oer.galileo.usg.edu/compsci-collections/8/

Topics include:

TCP/IP Level Attacks
Port Scanning
DDoS
Footprinting and Social Engineering
Enumeration
Programming for Security Professionals
Operating System Vulnerabilities
Embedded System Security
Hacking Web Servers
Hacking Wireless Networks
Cryptography
Protecting Networks with Security Devices

This course offers a broad survey of modern European history, from the end of the Thirty Years' War to the aftermath of World War II. Along with the consideration of major events and figures such as the French Revolution and Napoleon, attention will be paid to the experience of ordinary people in times of upheaval and transition. The period will thus be viewed neither in terms of historical inevitability nor as a procession of great men, but rather through the lens of the complex interrelations between demographic change, political revolution, and cultural development. Textbook accounts will be accompanied by the study of exemplary works of art, literature, and cinema.

ìExploring Imagery and Elevation Data in GIS Applicationsî (GEOG 480) focuses on the use of remotely sensed imagery and elevation data in GIS applications. Students enrolling in GEOG 480 should have a solid conceptual foundation in geospatial information science and technology. GEOG 480 is appropriate for those who are already working in the geospatial profession and wish to use imagery and elevation data in visualization and spatial analysis. Throughout the course, students confront realistic remote sensing problem scenarios that incorporate such skills and concepts as definition of data needs, metadata content standards, data formats and types, and analysis methods.

This open set of course materials for Film Aesthetics is a downloadable version of a course created for a learning management system. Included are learning modules and a quiz bank based on introductory film concepts including the following topics: Narrative Structure and Motifs, Mise-en-Scene, Cinematography, Sound Design, Music, and Visual Effects.

This course introduces participants to the financial risks and impacts associated with climate change. Participants will explore a range of risk pathways that link climate and economic systems, including:



• physical risks related to direct exposure to climate hazards in the value chain;

• transition risks arising from abrupt transitions to a low-carbon economy;

• systemic risks transmitted throughout the economy;

• extreme risks arising from the complex dynamic nature of climate-economy systems.

Financial institutions are a pillar of civilized society, supporting people in their productive ventures and managing the economic risks they take on. The workings of these institutions are important to comprehend if we are to predict their actions today and their evolution in the coming information age. The course strives to offer understanding of the theory of finance and its relation to the history, strengths and imperfections of such institutions as banking, insurance, securities, futures, and other derivatives markets, and the future of these institutions over the next century.

Course Contents 1. Turning performance (three dimensional equations of motion, coordinate systems, Euler angles, transformation matrices)
2. Airfield performance (take-off and landing)
3. Unsteady climb and descent (including minimum time to climb problem)
4. Cruise flight and transport performance
5. Equations of motion with a wind gradient present
6. Equations of motion applied to various phases of space flight
7. Launch, Vertical flight, delta-V budget, burn out height, staging
8. Gravity perturbations to satellite orbits, J2 effect for low earth orbit satellites, J2,2 effect for Geostationary Earth Orbit sattelites leading to contribution in V budget
9. Patched conics approach for interplanetary flight, gravity assist effect / options for change of excess velocity (2d, 3d), Launch, in orbit insertion.
Study Goals 1. Integrate fundamental disciplines (aero, power and propulsion, mechanics..) to describe the kinematics of aerospace vehicles satisfying real world constraints
2. Derive equations of motion for elementary flight and mission phases (climb, turn, cruise, take-off, launch, orbit)
3. Derive analytical expressions for optimal performance (steepest turn, Breguet Range, patched conics, J2, maneuvers )
4. Determine pros/cons of multi-stage launchers.
5. Assess sun lighting conditions on a satellite.
6. Determine the influence of wind (gradient) on aircraft motion and performance.
7. Develop the theory to describe an interplanetary trajectory as a succession of two-body problems, and apply this concept to real missions.

Students are introduced to the important concept of density with a focus is on the more easily understood densities of solids. Students use different methods to determine the densities of solid objects, including water displacement to determine volumes of irregularly-shaped objects. By comparing densities of various solids to the density of water, and by considering the behavior of different solids when placed in water, students conclude that ordinarily, objects with densities greater than water sink, while those with densities less than water float. Then they explore the principle of buoyancy, and through further experimentation arrive at Archimedes' principle that a floating object displaces a mass of water equal to its own mass. Students may be surprised to discover that a floating object displaces more water than a sinking object of the same volume.

Students are presented with an engineering challenge that asks them to develop a material and model that can be used to test the properties of aortic valves without using real specimens. Developing material that is similar to human heart valves makes testing easier for biomedical engineers because they can test new devices or ideas on the model valve instead of real heart valves, which can be difficult to obtain for research. To meet the challenge, students are presented with a variety of background information, are asked to research the topic to learn more specific information pertaining to the challenge, and design and build a (prototype) product. After students test their products and make modifications as needed, they convey background and product information in the form of portfolios and presentations to the potential buyer.