Courses tagged with "Information policy" (252)

Discover the big ideas and thinking practices in computer science plus learn how to code using one of the friendliest programming languages, Snap! (based on Scratch)

Computing has profoundly changed the world, opening up wonderful new ways for people to connect, design, research, play, create, and express themselves. However, just using a computer is only a small part of the picture. The real transformative and empowering experience comes when one learns how to program the computer, to translate ideas into code.

This course teaches students how to do exactly that, using Snap! (based on Scratch), one of the friendliest programming languages ever invented. It's purely graphical, which means programming involves simply dragging blocks around, and building bigger blocks out of smaller blocks. But this course is far more than just learning to program. We focus on seven big ideas (creativity, abstraction, data and information, algorithms, programming, the Internet, and global impact), and six computational thinking practices (connecting computing, creating computational artifacts, abstracting, analyzing problems and artifacts, communicating, and collaborating). Throughout the course, relevance is emphasized: relevance to the student and to society. This fun, introductory course is not just for computer science majors, it’s for everyone… join us!

“I am so grateful to have experienced BJC (Beauty and Joy of Computing). I took this course during my freshmen year at UC Berkeley, and it has actually changed my life. Because of it, I have switched to the computer science major and have even developed a passion for computer science education! This course showed me that computer science is creative, and it gave me the confidence to continue taking computer science courses. BJC's philosophy of inclusion, diversity, and collaboration is tangible and sets it apart from all other computer science courses that I have experienced. It is truly empowering!” -- Yifat Amir

Learn more about our High School and AP* Exam Preparation Courses

The Beauty and Joy of Computing (BJC) is a computer science principles course developed at the University of California, Berkeley, intended to broaden participation in computing to non-traditional groups. Computing has profoundly changed the world, opening up wonderful new ways for people to connect, design, research, play, create, and express themselves. However, just using a computer is only a small part of the picture. The real transformative and empowering experience comes when one learns how to program the computer, to translate ideas into code.

This course teaches students how to do exactly that, using Snap! (based on Scratch), one of the friendliest programming languages ever invented. It's purely graphical, which means programming involves simply dragging blocks around, and building bigger blocks out of smaller blocks. But this course is far more than just learning to program. We focus on seven big ideas (creativity, abstraction, data and information, algorithms, programming, the Internet, and global impact), and six computational thinking practices (connecting computing, creating computational artifacts, abstracting, analyzing problems and artifacts, communicating, and collaborating). Throughout the course, relevance is emphasized: relevance to the student and to society. This fun, introductory course is not just for computer science majors, it’s for everyone… join us!

Learn more about our High School and AP Courses

The Beauty and Joy of Computing (BJC) is a computer science principles course developed at the University of California, Berkeley, intended to broaden participation in computing to non-traditional groups. Computing has profoundly changed the world, opening up wonderful new ways for people to connect, design, research, play, create, and express themselves. However, just using a computer is only a small part of the picture. The real transformative and empowering experience comes when one learns how to program the computer, to translate ideas into code.

This course teaches students how to do exactly that, using Snap! (based on Scratch), one of the friendliest programming languages ever invented. It's purely graphical, which means programming involves simply dragging blocks around, and building bigger blocks out of smaller blocks. But this course is far more than just learning to program. We focus on seven big ideas (creativity, abstraction, data and information, algorithms, programming, the Internet, and global impact), and six computational thinking practices (connecting computing, creating computational artifacts, abstracting, analyzing problems and artifacts, communicating, and collaborating). Throughout the course, relevance is emphasized: relevance to the student and to society. This fun, introductory course is not just for computer science majors, it’s for everyone… join us!

Learn more about our High School and AP* Exam Preparation Courses

The Beauty and Joy of Computing (BJC) is a computer science principles course developed at the University of California, Berkeley, intended to broaden participation in computing to non-traditional groups. Computing has profoundly changed the world, opening up wonderful new ways for people to connect, design, research, play, create, and express themselves. However, just using a computer is only a small part of the picture. The real transformative and empowering experience comes when one learns how to program the computer, to translate ideas into code.

This course teaches students how to do exactly that, using Snap! (based on Scratch), one of the friendliest programming languages ever invented. It's purely graphical, which means programming involves simply dragging blocks around, and building bigger blocks out of smaller blocks. But this course is far more than just learning to program. We focus on seven big ideas (creativity, abstraction, data and information, algorithms, programming, the Internet, and global impact), and six computational thinking practices (connecting computing, creating computational artifacts, abstracting, analyzing problems and artifacts, communicating, and collaborating). Throughout the course, relevance is emphasized: relevance to the student and to society. This fun, introductory course is not just for computer science majors, it’s for everyone… join us!

Learn more about our High School and AP* Exam Preparation Courses

Chemistry and biology are traditionally taught as separate subjects at the high school level, where students memorize fundamental scientific principles that are universally accepted. However, at the university level and in industry, we learn that science is not as simple as we once thought. We are constantly confronted by questions about the unknown and required to use creative, integrated approaches to solve these problems. By bringing together knowledge from multidisciplinary fields, we are empowered with the ability to generate new ideas. The goal of this course is to develop skills for generating new ideas at the interface between chemistry and biology by analyzing pioneering studies.

When should I register?
Registration will be open throughout the course.

Using the American Civil War as a baseline, the course considers what it means to become "modern" by exploring the war's material and manpower needs, associated key technologies, and how both influenced the United States' entrance into the age of "Big Business." Readings include material on steam transportation, telegraphic communications, arms production, naval innovation, food processing, medicine, public health, management methods, and the mass production of everything from underwear to uniforms—all essential ingredients of modernity. Students taking the graduate version must complete additional assignments.

Using the American Civil War as a baseline, the course considers what it means to become "modern" by exploring the war's material and manpower needs, associated key technologies, and how both influenced the United States' entrance into the age of "Big Business." Readings include material on steam transportation, telegraphic communications, arms production, naval innovation, food processing, medicine, public health, management methods, and the mass production of everything from underwear to uniforms—all essential ingredients of modernity. Students taking the graduate version must complete additional assignments.

Albert Einstein has become the icon of modern science. Following his scientific, cultural, philosophical, and political trajectory, this course aims to track the changing role of physics in the 20^th and 21^st centuries. This history course addresses Einstein's engagement with relativity, quantum mechanics, Nazism, nuclear weapons, philosophy, the arts, and technology, and raises basic questions about what it means to understand physics in its broader history.
 
Participants in the course will follow seventeen lessons, each of which will present a mix of science (no prerequisites!) and the broader, relevant cultural surround.  Some weeks will examine the physics concepts, while others will see excerpts of films or discuss modernist poetry that took off from relativity. Or we might be looking at the philosophical roots and philosophical consequences of Einstein’s works.  At other times we will be fully engaged with historical and political questions: the building, dropping, and proliferation of nuclear weapons, for example. 
 
Typically, in a lesson (about an hour of streamed material), there will be opportunities for individual mini-essay writing, some multiple choice questions to bolster your understanding of the science, and a group activity which might one week be a debate and another a collective commentary on elements of an artwork from 1920s Weimar Germany.   

HarvardX requires individuals who enroll in its courses on edX to abide by the terms of the edX honor code : https://www.edx.org/edx-terms-service. HarvardX will take appropriate corrective action in response to violations of the edX honor code, which may include dismissal from the HarvardX course; revocation of any certificates received for the HarvardX course; or other remedies as circumstances warrant. No refunds will be issued in the case of corrective action for such violations. Enrollees who are taking HarvardX courses as part of another program will also be governed by the academic policies of those programs.

HarvardX pursues the science of learning. By registering as an online learner in an HX course, you will also participate in research about learning. Read our research statement : http://harvardx.harvard.edu/research-statement to learn more.

Harvard University and HarvardX are committed to maintaining a safe and healthy educational and work environment in which no member of the community is excluded from participation in, denied the benefits of, or subjected to discrimination or harassment in our program. All members of the HarvardX community are expected to abide by Harvard policies on nondiscrimination, including sexual harassment, and the edX Terms of Service. If you have any questions or concerns, please contact harvardx@harvard.edu and/or report your experience through the edX contact form : https://www.edx.org/contact-us.

This is an introductory astronomy survey class that covers our understanding of the physical universe and its major constituents, including planetary systems, stars, galaxies, black holes, quasars, larger structures, and the universe as a whole. We will learn how modern astronomical observations and applications of physics we know from the planet Earth reveal the nature of these objects and explain their observed properties, and tell us how they form and evolve. We will also examine various cosmic phenomena, from variable or exploding stars to the expansion of the universe and the evidence for dark matter, dark energy, and the big bang. The universe as a whole and all of its major constituents are evolving, and we now have a fairly complete and consistent picture of these processes that is based on the objective evidence from observations and the laws of physics. The goal of this class is both to learn about the fascinating objects and phenomena that populate the universe, and to understand how we know all that.

Life on our planet is diverse. While we can easily recognize this in our everyday surroundings, an even more diverse world of life can be seen when we look under a microscope. This is the world of microorganisms. Microorganisms are everywhere, and although some are notorious for their roles in human disease, many play important roles in sustaining our global environment. Among the wide variety of microorganisms, here we will explore those that thrive in the most extreme environments, the extremophiles.

In this course, we will discover how diverse life is on our planet and consider the basic principles that govern evolution. We will also learn how we can classify organisms. Following this, we will have a look at several examples of extreme environments, and introduce the microorganisms that thrive under these harsh conditions. We will lay emphasis on the thermophiles, extremophiles that grow at high temperatures and will study how proteins from thermophiles can maintain their structure and function at high temperatures.

This course focuses on one particular aspect of the history of computing: the use of the computer as a scientific instrument. The electronic digital computer was invented to do science, and its applications range from physics to mathematics to biology to the humanities. What has been the impact of computing on the practice of science? Is the computer different from other scientific instruments? Is computer simulation a valid form of scientific experiment? Can computer models be viewed as surrogate theories? How does the computer change the way scientists approach the notions of proof, expertise, and discovery? No comprehensive history of scientific computing has yet been written. This seminar examines scientific articles, participants’ memoirs, and works by historians, sociologists, and anthropologists of science to provide multiple perspectives on the use of computers in diverse fields of physical, biological, and social sciences and the humanities. We explore how the computer transformed scientific practice, and how the culture of computing was influenced, in turn, by scientific applications.

To study MIT is to study the modern world. In 2016, MIT celebrated the 100^th anniversary of the move from Boston to Cambridge; therefore, this course examines the history of the Institute through the lens of the history of science and technology, and vice-versa. It is about discovery, exploration, adventure, learning, creative thinking, and the synthesis of big ideas. Additionally, this course is about the importance of the research university, what it has been in the past and what it will be in the future. The course includes guest lecturers and field trips to the Institute Archives and the MIT Museum.

The most important prerequisite for this class is curiosity, a desire to think deeply about MIT, and a willingness to communicate your thoughts and ideas. The ultimate aim is to fascinate you as much as to help you improve your skills synthesizing information from diverse sources about science, technology, and culture.

3.086x: The Iterative Innovation Process draws heavily upon the course material used in 3.086x: Innovation and Commercialization. Though there have been significant changes to the course, this course is not an entirely new edX offering.

People innovate, not organizations. This course is for anybody who wants to understand the innovation process - whether you want to foster innovation within your organization or whether you want to personally innovate.

As practicing innovators, we teach you the fundamentals of how to think like an innovator. Innovation is an iterative process, not a linear one. When innovating, there are thousands of sources of uncertainty in Technology, Implementation, and Markets. We teach you how to cycle through these sources of uncertainty until the right pieces come together in an innovation.

Throughout the course, we build up the innovation process model step by step with real examples and exercises. The goal of this course is to change and refine the way you view the innovation process, providing you with the foundation on which to build your future innovation

This subject introduces the history of science from antiquity to the present. Students consider the impact of philosophy, art, magic, social structure, and folk knowledge on the development of what has come to be called "science" in the Western tradition, including those fields today designated as physics, biology, chemistry, medicine, astronomy and the mind sciences. Topics include concepts of matter, nature, motion, body, heavens, and mind as these have been shaped over the course of history. Students read original works by Aristotle, Vesalius, Newton, Lavoisier, Darwin, Freud, and Einstein, among others.

What exactly are genetically modified organisms (GMOs) and why do scientists develop them? Studying the science of GMOs helps us understand biotechnology’s potential role in addressing challenges in agriculture.

In this introductory Food and Nutrition course, you will learn the basics of genetic engineering, explore the political debate around the GMO and review the arguments for and against their use.

We will study the politics surrounding the GMO and its impact at both an individual level and to society as a whole; including the problems, perceptions, benefits, and risks associated with GMOs. Important to understanding the complexities around this topic we will not only be looking at the science behind how the GMO works, but also to the limitations of this science. We will also discuss the importance of information literacy as a tool for effectively identifying and evaluating issues.

Our goal is that this MOOC will impact people's understanding of science, what it can and can't do, and how information is transmitted. The intent is not to influence how people feel about GMOs, but to give them the critical thinking and scientific literacy tools necessary to make informed decisions — and to understand the broader impacts of those decisions.

This course introduces the origin and key concepts of sustainability and how to apply those to sustainable development practice.

Sustainable development will be explored through theories and case studies from a range of Disciplines. You also will learn about planetary boundaries, urbanisation and growing inequality, to show how integral sustainable development is to our everyday existence.

This course will attempt to provide key content knowledge to bridge the science and the practice of the application and enhancement of sustainable development. The course draws on contemporary examples from both The University of Queensland (UQ) and the Sustainable Development Solutions Network (SDSN) to address the world’s most urgent challenges, with emphasis on the linkages between science and policy.

We will explore the psychology of our everyday thinking: why people believe weird things, how we form and change our opinions, why our expectations skew our judgments, and how we can make better decisions. We’ll discuss and debate topics such as placebos, the paranormal, medicine, miracles, and more.

You will use the scientific method to evaluate claims, make sense of evidence, and understand why we so often make irrational choices. You will begin to rely on slow, effortful, deliberative, analytic, and logical thinking rather than fast, automatic, instinctive, emotional, and stereotypical thinking.

We will provide tools for how to think independently, how to be skeptical, and how to value data over personal experience. We will examine the mental shortcuts that people use and misuse, and apply this knowledge to help make better decisions, and improve critical thinking.

ME209.1x is a basic course in thermodynamics, designed for students of mechanical engineering. We will study the terms and concepts used in thermodynamics, with precise definitions. The three laws of thermodynamics (zeroth, first, and second) will be explored in detail, and the properties of materials will be studied. Many useful relations will be derived. The topics include:

• basic concepts and definitions
• the work interaction
• the first law, energy, and the heat interaction
• the zeroth law, temperature, and scales of temperature
• properties of gases and liquids, equations of state
• the second law, thermodynamic temperature scales, and entropy
• relations between properties
• open thermodynamic systems

There will be emphasis on problem-solving. Students will need to spend significant effort on solving exercises.

The course is designed for students in mechanical engineering. However, others (both engineers and scientists) are likely to find it useful. The course has also been found to be useful to teachers of thermodynamics.

Please note that this course is self-paced and you can enroll at any time.  At normal pace, this course requires 12 weeks of study, about 10 hours a week.

Alzheimer’s disease is one of the most financially costly disease in developed countries. Even if knowledge of molecular changes in Alzheimer’s disease is extensive, and new areas of investigation have been explored, the cognitive trajectory of Alzheimer’s disease is still unknown, as it was in 1906, when this disease was described for the first time.

This self-paced course focuses on a recent and innovative approach in the field of Alzheimer’s disease research. Multiple evidences indicate that oxidative stress and free radicals damage the cellular functions. Specifically, oxidative damage is a marker to identify the initial state of the disease.

Starting from a critical analysis of Alzheimer’s disease history, Dr. Perry, a worldwide expert in the field, explains the sequence of events leading to damage, and the source of increased oxygen radicals along with mechanisms to provide more effective treatment.

This course is open to anyone, but will be of particular relevance to professionals and caregivers who deal with patients affected by Alzheimer’s. Considering the multidisciplinary approach, and the importance of a correct lifestyle to prevent and treat Alzheimer’s disease, this course is also targeted to healthcare professionals such as nutritionists or cardiologists.