Online courses directory (2511)

This course explores how and why Japan, a late-comer to modernization, emerged as an industrial power and the world's second-richest nation, notwithstanding its recent difficulties. We are particularly concerned with the historical development of technology in Japan especially after 1945, giving particular attention to the interplays between business, ideology, technology, and culture. We will discuss key historical phenomena that symbolize modern Japan as a technological power in the world; specific examples to be discussed in class include kamikaze aircraft, the Shinkansen high-speed bullet train, Godzilla, and anime.

This course explores the values (aesthetic, moral, cultural, religious, prudential, political) expressed in the choices of food people eat. It analyzes the decisions individuals make about what to eat, how society should manage food production and consumption collectively, and how reflection on food choices might help resolve conflicts between different values.

This course analyzes contemporary Chinese politics, both pre-Communist and Communist. It focuses on the process of modernization and political development of Chinese civilization. Graduate students are expected to pursue the subject at greater depth through reading and individual research.

The objective of this course is to introduce you to the role of government in markets where competitive equilibria “fail.” In this course we will emphasize the importance of market structure and industrial performance, including the strategic interaction of firms. We will examine the behavior of individual markets in some detail, focusing on cost analysis, the determinants of market demand, investment behavior, market power, and the implications of government regulatory behavior. The course will be broken into three parts. In the first part, we will review firm behavior and the theory of the market. Here, we will discuss perfectly competitive markets (our “benchmark”), efficiency, market structure, strategic competition, and productivity. Once the foundations of the market are well understood, we will then move on to the second part of the course, where we will study “economic” regulation. Here, we will look at the behavior of natural monopolies and regulatory options for dealing with them. And in the third part of the course, we will study “social” regulation—focusing on environmental, health, and safety regulation.

This is a freshman advising seminar. The professor of a FAS is the first year advisor to the (no more than 8) students in the seminar.

The use of Global Positioning System (GPS) in a wide variety of applications has exploded in the last few years. In this seminar we explore how positions on the Earth were determined before GPS; how GPS itself works and the range of applications in which GPS is now a critical element. This seminar is followed by a UROP research project in the spring semester where results from precise GPS measurements will be analyzed and displayed on the Web.

The tools and analytical methods that biochemists use to dissect biological problems. Analysis of the mode of action and structure of regulatory, binding, and catalytic proteins.

This is the second in a sequence of two field seminars in American politics intended for graduate students in political science, in preparation for taking the general examination in American politics. The material covered in this semester focuses on American political institutions. The readings covered here are not comprehensive, but it is sufficiently broad to give students an introduction to major empirical questions and theoretical approaches that guide the study of American political institutions these days.

This is a literature seminar with a focus on classic papers in Algebraic Topology. It is named after the late MIT professor Daniel Kan. Each student gives one or two talks on each of three papers, chosen in consultation with the instructor, reads all the papers presented by other students, and writes reactions to the papers. This course is useful not only to students pursuing algebraic topology as a field of study, but also to those interested in symplectic geometry, representation theory, and combinatorics.

This course is designed to allow participants to engage in the exploration of the grammatical structure of a language that is unknown to them (and typically to the instructors as well). In some ways it simulates traditional field methods research. In terms of format, we work in both group and individual meetings with the consultant. Each student identifies some grammatical construction (e.g. wh questions, agreement, palatalization, interrogative intonation) to focus their research: they elicit and share data and write a report on the material gathered that is to be turned in at the end of the term. Ideally, we can put together a volume of grammatical sketches.

The first three to four weeks of the term, our group meetings will explore the basic phonology, morphology and surface syntax for a first pass overview of the language, looking for interesting areas to be explored in more detail later. During this period individual sessions can review material from the general session as well as explore new areas. At roughly the fifth meeting, individual students (typically two to three per session) guide the group elicitations to explore their research topic.

This course provides a challenging introduction to some of the central ideas of theoretical computer science. It attempts to present a vision of "computer science beyond computers": that is, CS as a set of mathematical tools for understanding complex systems such as universes and minds. Beginning in antiquity—with Euclid's algorithm and other ancient examples of computational thinking—the course will progress rapidly through propositional logic, Turing machines and computability, finite automata, Gödel's theorems, efficient algorithms and reducibility, NP-completeness, the P versus NP problem, decision trees and other concrete computational models, the power of randomness, cryptography and one-way functions, computational theories of learning, interactive proofs, and quantum computing and the physical limits of computation. Class participation is essential, as the class will include discussion and debate about the implications of many of these ideas.

This course provides a challenging introduction to some of the central ideas of theoretical computer science. It attempts to present a vision of "computer science beyond computers": that is, CS as a set of mathematical tools for understanding complex systems such as universes and minds. Beginning in antiquity—with Euclid's algorithm and other ancient examples of computational thinking—the course will progress rapidly through propositional logic, Turing machines and computability, finite automata, Gödel's theorems, efficient algorithms and reducibility, NP-completeness, the P versus NP problem, decision trees and other concrete computational models, the power of randomness, cryptography and one-way functions, computational theories of learning, interactive proofs, and quantum computing and the physical limits of computation. Class participation is essential, as the class will include discussion and debate about the implications of many of these ideas.

The purpose of this seminar is to examine systematically, and comparatively, great and middle power military interventions into civil wars during the 1990's. These civil wars were high on the policy agenda of western states during the 1990's. Yet, these interventions were usually not motivated by obvious classical vital interests. Given the extraordinary security enjoyed by the great and middle powers of the west in the Cold War's aftermath, these activities are puzzling.

This course examines systematically, and comparatively, great and middle power military interventions, and candidate military interventions, into civil wars from the 1990s to the present. These civil wars did not easily fit into the traditional category of vital interest. These interventions may therefore tell us something about broad trends in international politics including the nature of unipolarity, the erosion of sovereignty, the security implications of globalization, and the nature of modern western military power.

The half-semester graduate course in Green Supply Chain Management will focus on the fundamental strategies, tools and techniques required to analyze and design environmentally sustainable supply chain systems. Topics covered include: Closed-loop supply chains, reverse logistics systems, carbon footprinting, life-cycle analysis and supply chain sustainability strategy.

Class sessions will combine presentations, case discussions and guest speakers. All students will work on a course-long team project that critically evaluates the environmental supply chain strategy of an industry or a publicly traded company. Grades will be based on class participation, case study assignments and the team project.

This course covers fundamentals of subsurface flow and transport, emphasizing the role of groundwater in the hydrologic cycle, the relation of groundwater flow to geologic structure, and the management of contaminated groundwater. The class includes laboratory and computer demonstrations.

This class introduces the student to the use of small telescopes, either for formal research or as a hobby.

This course covers background for and techniques of visual observation, electronic imaging, and spectroscopy of the Moon, planets, satellites, stars, and brighter deep-space objects. Weekly outdoor observing sessions using 8-inch diameter telescopes when weather permits. Indoor sessions introduce needed skills. Introduction to contemporary observational astronomy including astronomical computing, image and data processing, and how astronomers work. Student must maintain a careful and complete written log which is graded. (Limited enrollment with priority to freshmen. Consumes an entire evening each week; 100% attendance at observing sessions required to pass.)

This course introduces students to both passive and active electronic components (op-amps, 555 timers, TTL digital circuits). Basic analog and digital circuits and theory of operation are covered. The labs allow the students to master the use of electronic instruments and construct and/or solder several circuits. The labs also reinforce the concepts discussed in class with a hands-on approach and allow the students to gain significant experience with electrical instruments such as function generators, digital multimeters, oscilloscopes, logic analyzers and power supplies. In the last lab, the students build an electronic circuit that they can keep. The course is geared to freshmen and others who want an introduction to electronics circuits.

This course is offered 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.

In this subject we will study the basic harmonic, melodic, and formal practices of western music, principally the classical music of central Europe during the eighteenth century. Topics will include diatonic harmony, simple counterpoint in two parts, and tones of figuration. The coursework will combine composition, listening, analysis, and work in sight-singing and keyboard musicianship.

In this subject, we explore the harmonic, melodic, and formal practices of western music, principally the so-called "Classical" idiom of central Europe, ca. 1750-1825. Topics include a quick review of material covered in 21M.301, chromatic harmony (vii^o7, bII⁶, and chords of the augmented sixth), and chromatic modulation; lecture study and discussion are complemented by work in the keyboard laboratory and sight-singing laboratory. All areas of study will be integrated in a semester-long project of composing a theme and two variations in Classical style.

This course is a collaborative offering of Sana, Partners in Health, and the Institute for Healthcare Improvement (IHI). The goal of this course is the development of innovations in information systems for developing countries that will (1) translate into improvement in health outcomes, (2) strengthen the existing organizational infrastructure, and (3) create a collaborative ecosystem to maximize the value of these innovations. The course will be taught by guest speakers who are internationally recognized experts in the field and who, with their operational experiences, will outline the challenges they faced and detail how these were addressed.