The purpose of this lesson is to teach the students about how …
The purpose of this lesson is to teach the students about how a spacecraft gets from the surface of the Earth to Mars. The lesson first investigates rockets and how they are able to get us into space. Finally, the nature of an orbit is discussed as well as how orbits enable us to get from planet to planet specifically from Earth to Mars.
This activity is an easy way to demonstrate the fundamental properties of …
This activity is an easy way to demonstrate the fundamental properties of polar and non-polar molecules (such as water and oil), how they interact, and the affect surfactants (such as soap) have on their interactions. Students see the behavior of oil and water when placed together, and the importance soap (a surfactant) plays in the mixing of oil and water which is why soap is used every day to clean greasy objects, such as hands and dishes. This activity is recommended for all levels of student, grades 3-12, as it can easily be scaled to meet any desired level of difficulty.
Students are introduced to gear transmissions and gear ratios using LEGO MINDSTORMS(TM) …
Students are introduced to gear transmissions and gear ratios using LEGO MINDSTORMS(TM) NXT robots, gears and software. They discover how gears work and how they can be used to adjust a vehicle's power. Specifically, they learn how to build the transmission part of a vehicle by designing gear trains with different gear ratios. Students quickly recognize that some tasks require vehicle speed while others are more suited for vehicle power. They are introduced to torque, which is a twisting force, and to speed the two traits of all rotating engines, including mobile robots using gears, bicycles and automobiles. Once students learn the principles behind gear ratios, they are put to the test in two simple design activities that illustrate the mechanical advantages of gear ratios. The "robot race" is better suited for a quicker robot while the "robot push" calls for a more powerful robot. A worksheet and post-activity quiz verify that students understand the concepts, including the tradeoff between torque and speed.
Students take part in a hypothetical scenario that challenges them to inform …
Students take part in a hypothetical scenario that challenges them to inform customers at a local restaurant of how their use and disposal of plastics relates/contributes to the Great Pacific garbage patch (GPGP). What students ultimately do is research information on the plastics pollution in the oceans and present that information as a short, eye-catching newsletter suitable to hand out to restaurant customers. This activity focuses on teaching students to conduct their own research on a science-technology related topic and present it in a compelling manner that includes citing source information without plagiarism. By doing this, students gain experience and skills with general online searching as well as word processing and written and visual communication.
An old saying holds that ŰĎthere are many more good ideas in …
An old saying holds that ŰĎthere are many more good ideas in the world than good ideas implemented.Ű This is a case-based introduction to the fundamentals of effective implementation. Developed with the needs and interests of planners--but also with broad potential application--in mind, this course is a fast-paced, case-driven introduction to developing strategy for organizations and projects, managing operations, recruiting and developing talent, taking calculated risks, measuring results (performance), and leading adaptive change, for example where new mental models and habits are required but also challenging to promote. Our cases are set in the U.S. and the developing world and in multiple work sectors (urban redevelopment, transportation, workforce development, housing, etc.). We will draw on public, private, and nonprofit implementation concepts and experience.
In this lesson, students will investigate error. As shown in earlier activities …
In this lesson, students will investigate error. As shown in earlier activities from navigation lessons 1 through 3, without an understanding of how errors can affect your position, you cannot navigate well. Introducing accuracy and precision will develop these concepts further. Also, students will learn how computers can help in navigation. Often, the calculations needed to navigate accurately are time consuming and complex. By using the power of computers to do calculations and repetitive tasks, one can quickly see how changing parameters likes angles and distances and introducing errors will affect their overall result.
In this lesson, students learn how to determine location by triangulation. We …
In this lesson, students learn how to determine location by triangulation. We describe the process of triangulation and practice finding your location on a worksheet, in the classroom, and outdoors.
In this activity students practice measuring techniques by measuring different objects and …
In this activity students practice measuring techniques by measuring different objects and distances around the classroom. They practice using different scales of measurement in metric units and estimation.
This hands-on activity explores five different forms of erosion (chemical, water, wind, …
This hands-on activity explores five different forms of erosion (chemical, water, wind, glacier and temperature). Students rotate through stations and model each type of erosion on rocks, soils and minerals. The students record their observations and discuss the effects of erosion on the Earth's landscape. Students learn about how engineers are involved in the protection of landscapes and structures from erosion. Math problems are included to help students think about the effects of erosion in real-world scenarios.
Students learn how the greenhouse effect is related to global warming and …
Students learn how the greenhouse effect is related to global warming and how global warming impacts our planet, including global climate change. Extreme weather events, rising sea levels, and how we react to these changes are the main points of focus of this lesson.
GEM4 VisionGEM4 has brought together researchers and professionals in major institutions across …
GEM4 VisionGEM4 has brought together researchers and professionals in major institutions across the globe with distinctly different, but complementary, expertise and facilities to address significant problems at the intersections of select topics of engineering, life sciences, technology, medicine and public health.GEM4 creates new models for interactions across scientific disciplinary boundaries whereby problems spanning the range of fundamental science to clinical studies and public health can be addressed on a global scale through strategic international partnerships.Through initial focus areas in cell and molecular biomechanics, and environmental health, in the context of select human diseases, GEM4 creates a global forum for the definition and exploration of grand challenges and scientific studies, for the cross-fertilization of ideas among engineers, life scientists and medical professionals, and for the development of novel educational tools.GEM4 ActivitiesGEM4 enables the brokering of engineers, life scientists and medical professionals with shared facilities and joint students and post-doctoral fellows to tackle major problems in the context of human health and diseases that call for state-of-the-art experimental and computational tools in cell and molecular mechanics, biology and medicine. Broad examples of problems addressed include:infectious diseases such as malaria,cancer,cardiovascular diseases,biomechanical origins of inflammation.In each of these areas, the initial emphasis has included (but will not be limited to) molecular, subcellular and cellular mechanics applied to biomedicine, where a single investigator or institution is not likely to have the full spectrum of expertise, infrastructure or resources available to cover fundamental molecular science all the way to clinical studies and societal implications. Currently, twelve institutions in North America, Europe and Asia participate in this effort as Core institutions, focusing on mechanistic studies, as well as novel methods for diagnostics, vaccines or drug development and delivery.Funds have been raised to provide a structure for coordinated studies from major organizations under the umbrella of GEM4. These funds are being used for:organization of major symposia/conferences specifically targeted at the theme areas of the initiative,training grants for student fellowships for the partner institutions,summer schools to develop teaching materials,the exchange of students and researchers,operations of a central secretariat for handling the administrative and infrastructure details for such interactions,maintenance of a web site for dissemination of information.
For the first time in history, the global demand for freshwater is …
For the first time in history, the global demand for freshwater is overtaking its supply in many parts of the world. The U.N. predicts that by 2025, more than half of the countries in the world will be experiencing water stress or outright shortages. Lack of water can cause disease, food shortages, starvation, migrations, political conflict, and even lead to war. Models of cooperation, both historic and contemporary, show the way forward. The first half of the course details the multiple facets of the water crisis. Topics include water systems, water transfers, dams, pollution, climate change, scarcity, water conflict/cooperation, food security, and agriculture. The second half of the course describes innovative solutions: Adaptive technologies and adaptation through policy, planning, management, economic tools, and finally, human behaviors required to preserve this precious and imperiled resource. Several field trips to water/wastewater/biosolids reuse and water-energy sites will help us to better comprehend both local and international challenges and solutions.
This course will study the question of Global Architecture from the point …
This course will study the question of Global Architecture from the point of view of producing a set of lectures on that subject. The course will be run in the form of a writing seminar, except that students will be asked to prepare for the final class an hour-long lecture for an undergraduate survey course. During the semester, students will study the debates about where to locate the global" and do some comparative analysis of various textbooks. The topic of the final lecture will be worked on during the semester. For that lecture, students will be asked to identify the themes of the survey course, and hand in the bibliography and reading list for their lecture."
Software engineering operates ever more frequently in globally distributed settings, in a …
Software engineering operates ever more frequently in globally distributed settings, in a practice that is known as Globally Distributed Software Engineering (GDSE). In this course, you will obtain a practical overview of the organization and operation of software engineering of this practice. As such, it is aimed at professionals in distributed software development teams, and executives setting up and leading such teams who would like to develop the required technical and organizational skills.
The course covers the subject in an accessible and practical manner. Through video lectures, group assignments and exercises, you will be familiarized with the advantages and disadvantages of GDSE, the practical consequences of GDSE and its technological feasibilities and infeasibilities. You will learn about real-world experiences of users and examples of GDSE applications such as outsourcing, offshore software development, near-shoring and multi-partner systems development.
You will apply the knowledge gained through hands-on experience with GDSE by working together with team members from different countries as a distributed team; and through analysis of best-practice examples. Together with other course participants you will prepare a number of artefacts that build on the body of knowledge of GDSE and so have the chance to contribute to this growing field of knowledge.
Guest lectures from industry experts and researchers will be an integral part of the course. These lectures will demonstrate how GDSE is handled in industry, how decision-makers lead their teams in this context, and what is the state-of-the-art in GDSE research
Students learn about the engineering design process and how products may be …
Students learn about the engineering design process and how products may be reinvented to serve new purposes. Working in groups, students design a type of slime. After creating their slime, the teacher turns out the lights and the students see that the slime they made actually glows in the dark! The groups investigate how to take their new discoveries and apply them to industrial applications. Once they have determined a use for their glowing slime, each group must build/design and test their product outside of class. The groups then create advertisements (videos, brochures, performances, etc.) for their new product(s) or application(s), and present to the judges for review similar to a “Shark Tank” environment.
Student teams learn about engineering design of green fluorescent proteins (GFPs) and …
Student teams learn about engineering design of green fluorescent proteins (GFPs) and their use in medical research, including stem cell research. They simulate the use of GFPs by adding fluorescent dye to water and letting a flower or plant to transport the dye throughout its structure. Students apply their knowledge of GFPs to engineering applications in the medical, environmental and space exploration fields. Due to the fluorescing nature of the dye, plant life of any color, light or dark, can be used unlike dyes that can only be seen in visible light.
Students combine art, gaming culture and engineering by fabricating light-up patches to …
Students combine art, gaming culture and engineering by fabricating light-up patches to increase youngsters’ visibility at night. The open-ended project is presented as a hypothetical design challenge: Students are engineers who have been asked by a group of parents whose children go out Pokémon hunting at night to create glowing patches that they adhere to clothing or backpacks to help vehicle drivers see the kids in the dark. Student pairs create Pokémon character stencil designs cut from iron-on fabric patches, adding transparent layers for color. Placed over an EL (electroluminescent) panel that is connected to a battery pack, the stencils create glowing designs. Each team creates a circuit, which includes lengthening the EL panel wiring to make it easier to wear. Then they sew/adhere the patches onto hoodies, messenger bags, hats, pockets or other applications they dream up. The project concludes with team presentations as if to an audience of project clients. Keep the project simple by hand cutting and ironing/sewing, or use cutting machines, laser cutters and sewing machines, if available.
Students will answer the Challenge Question and use the acquired learning from …
Students will answer the Challenge Question and use the acquired learning from Lesson 1, "Fix the Hip Challenge" and Lesson 2, "Skeletal System Overview"to construct an informative brochure addressing osteoporosis and the role biomedical engineering plays in diagnosing and preventing this disease.
No restrictions on your remixing, redistributing, or making derivative works. Give credit to the author, as required.
Your remixing, redistributing, or making derivatives works comes with some restrictions, including how it is shared.
Your redistributing comes with some restrictions. Do not remix or make derivative works.
Most restrictive license type. Prohibits most uses, sharing, and any changes.
Copyrighted materials, available under Fair Use and the TEACH Act for US-based educators, or other custom arrangements. Go to the resource provider to see their individual restrictions.
