This course focuses on an in-depth reading of Principia Mathematica Philosophiae Naturalis by Isaac Newton, as well as several related commentaries and historical philosophical texts.

This class examines the history and theory of historic preservation, focusing on the United States, but with reference to traditions and practices in other countries. The class is designed to examine the largely untold history of the historic preservation movement in this country, and explore what laws, public policies and cultural attitudes shape how we preserve or do not preserve the built environment. The class will give students a grounding in the history, theory and practice of historic preservation, but is not an applied, technical course.

Examines the development of computing techniques and technology in the nineteenth and twentieth centuries, particularly critical evaluation of how the very idea of "computer" changes and evolves over time. Emphasis is on technical innovation, industrial development, social context, and the role of government. Topics include Babbage, Hollerith, differential analyzers, control systems, ENIAC, radar, operations research, computers as scientific instruments, the rise of "computer science," artificial intelligence, personal computers, and networks. Includes class visits by members of the MIT community who have made important historical contributions. 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.

This course examines the history of MIT through the lens of the broader history of science and technology, and vice versa. The course covers the founding of MIT in 1861 and goes through the present, including such topics as William Barton Rogers, educational philosophy, biographies of MIT students and professors, intellectual and organizational development, the role of science, changing laboratories and practices, and MIT's relationship with Boston, the federal government, and industry. Assignments include short papers, presentations, and final paper. A number of classes are concurrent with the MIT150 Symposia.

History of Media and Technology addresses the mutually influential histories of communications media and technological development, focusing on the shift from analog to digital cultures that began mid-century and continues to the present. The approach the series takes to the study of media and technology is a multifaceted one that includes theoretical and philosophical works, histories canonical and minority, literature and art, as well as hands-on production issues toward the advancement of student projects and research papers. The topic for this term is Eternal War.

This course offers an introduction to the history and historiography of science from ancient Greece to the present. It is designed to serve as an introduction for those who have no prior background in the field and to deepen the knowledge of those who already do. We will consider how the history of science has responded to its encounters with philosophy, sociology, economics, and anthropology. Our readings and discussions will focus on determining what makes particular works effective, understanding major contemporary trends and debates in the history of science, and establishing resources for further research.

Examines the development of the western intellectual tradition from the fall of the Roman Empire through the High Middle Ages. Basic premise is that the triumph of Christianity in Europe was not the inevitable outcome it appears from hindsight. Attention is therefore focused not only on the development of Christian thought and practice, but on its challengers as well. Particular emphasis devoted to Nordic paganism, the rise of Islam, Byzantine orthodoxy, indigenous heretical movements, and the ambiguous position of Jews in European society.

A laboratory-based exploration of the principles, techniques, and applications of holography as a 3-D imaging communication medium. Begins with interference and diffraction, and proceeds through laser off-axis holography to white-light "rainbow" and reflection holography. Term project required, with oral presentation and written report. MAS.450 is a laboratory course about holography and holographic imaging. This course teaches holography from a scientific and analytical point of view, moving from interference and diffraction to imaging of single points to the display of three-dimensional images. Using a "hands-on" approach, students explore the underlying physical phenomena that make holograms work, as well as designing laboratory setups to make their own images. The course also teaches mathematical techniques that allow the behavior of holography to be understood, predicted, and harnessed. Holography today brings together the fields of optics, chemistry, computer science, electrical engineering, visualization, three-dimensional display, and human perception in a unique and comprehensive way. As such, MAS.450 offers interesting and useful exposure to a wide range of principles and ideas. As a course satisfying the Institute Laboratory Requirement, MAS.450 teaches about science, scientific research, and the scientific method through observation and exploration, hinting at the excitement that inventors feel before they put their final equations to paper.

"This course covers the same material as Differential Equations (18.03) with more emphasis on theory. In addition, it treats mathematical aspects of ordinary differential equations such as existence theorems."

Focuses on how the housing and human service systems interact: how networks and social capital can build between elements of the two systems. Explores ways in which the differing world views, professional perspectives, and institutional needs of the two systems play out operationally. Part I establishes the nature of the action frames of these two systems. Part II applies these insights to particular vulnerable groups: "at risk" households in transitional housing, the chronically mentally ill, and the frail elderly.

This is an activity about ultraviolet light. Learners will make ultraviolet light detector bracelets and use them to experiment with artificial light and sunlight. Then, they experiment with various sun-blocking materials to see how such materials impact the beads' absorption of ultraviolet light. Special UV detecting beads are required for this activity. This is Activity 3 of the Sun As a Star afterschool curriculum.

This is an activity about comparing images of the Sun in different wavelengths of light. Learners will examine solar images taken by the SOHO spacecraft to look for differences in the features that are visible in the various wavelengths of light. This activity requires access to the internet to view or print images of the Sun. This is Activity 7 of the Sun As a Star afterschool curriculum.

Through six lesson/activity sets, students learn about the functioning of sensors, both human and robotic. In the activities, student groups use LEGO MINDSTORMS(TM) NXT robots and components to study human senses (sight, hearing, smell, taste, touch) in more detail than in previous units in the series. They also learn about the human made rotation, touch, sound, light and ultrasonic sensors. "Stimulus-sensor-coordinator-effector-response" pathways are used to describe the processes as well as similarities between human/animal and robotic equivalent sensory systems. The important concept of sensors converting/transducing signals is emphasized. Through assorted engineering design challenges, students program the LEGO robots to respond to input from various LEGO sensors. The overall framework reinforces the theme of the human body as a system with sensors that is, from an engineering perspective. PowerPoint® presentations, quizzes and worksheets are provided throughout the unit.

This is an activity about how light travels. Learners will perform two experiments. The first explores blocking light to create shadows. The second asks learners to use mirrors to figure out that light travels in a straight line. This is Activity 4 of the Sun As a Star afterschool curriculum. This activity requires use of a room that can be darkened.

Subject studies how and why machines work, how they are conceived, how they are developed (drawn), and how they are utilized. Students learn from the hands-on experiences of taking things apart mentally and physically, drawing (sketching, 3D CAD) what they envision and observe, taking occasional field trips, and completing an individual term project (concept, creation, and presentation). Emphasis on understanding the physics and history of machines.

In this lesson, students explore how digital devices encode complex information so that it can be transferred over long distances. In the activity, Secret Snacks, students generate their own codes in order to transfer information across the classroom. Then, they compare their codes and evaluate which worked best given the criteria and constraints.

Firms must develop major innovations to prosper, but they don't know how to. However, recent research into the innovation process has made it possible to develop breakthroughs systematically. 15.356 How to Develop Breakthrough Products and Services explores several practical idea generation development methods. To convey the art required to implement each of these methodologies, experts are invited to present real cases to the class.

Examines how new computational tools and activities can help people learn new things in new ways. Discusses theories of learning and education underlying the design and use of these tools, and explores how new tools can change the ways people think about learning and education. Special emphasis on "constructionist" approaches to learning (represented by tools such as StarLogo and programmable LEGO bricks). Final project involves the design and observation of learning activities. As the digital revolution brings with it radical changes in how and what we learn, people must continue to learn all the time. New technologies make possible new approaches to learning, new contexts for learning, new tools to support learning, and new ideas of what can be learned. This course will explore these new opportunities for learning with a special focus on what can be learned through immersive, hands-on activities. Students will participate in (and reflect on) a variety of learning situations, and will use Media Lab technologies to develop new workshops, iteratively run and refine the workshops, and analyze how and what the workshop participants learn.

Provides a hands-on introduction to the resources for designing and fabricating smart systems, including CAD/CAM/CAE; NC machining, 3-D printing, injection molding, laser cutting; PCB layout and fabrication; sensors and actuators; analog instrumentation; embedded digital processing; wired and wireless communications. Emphasis on learning how to use the tools as well as understand how they work.

This course is an introduction to data cleaning, analysis and visualization. We will teach the basics of data analysis through concrete examples. You will learn how to take raw data, extract meaningful information, use statistical tools, and make visualizations. This was offered as a non-credit course during the Independent Activities Period (IAP), which is a special 4-week term at MIT that runs from the first week of January until the end of the month.