Courses tagged with "Nutrition" (6413)

This course comprises of a seminar on planning and operation of modern electric power systems. Content varies with current interests of instructor and class; emphasis on engineering aspects, but economic issues may be examined too. Core topics include: overview of power system structure and operation; representation of components, including transmission lines, transformers, generating plants, loads; power flow analysis, dynamics and control of multimachine systems, steady-state and transient stability, system protection; economic dispatch; mobile and isolated power systems; computation and simulation.

Required for all Earth, Atmospheric, and Planetary Sciences majors in the Environmental Science track, this course is an introduction to current research in the field. Stresses integration of central scientific concepts in environmental policy making and the chemistry, biology, and geology environmental science tracks. Revisits selected core themes for students who have already acquired a basic understanding of environmental science concepts. The topic for this term is geoengineering.

This advanced course in anthropology engages closely with discussions and debates about ethnographic research, ethics, and representation.

In this course, students take turns in giving lectures. For the most part, the lectures are based on Robert Osserman's classic book A Survey of Minimal Surfaces, Dover Phoenix Editions. New York: Dover Publications, May 1, 2002. ISBN: 0486495140.

The main objective of this cross-disciplinary course is to understand the historical development and the current status of ideas and models, to present and question the constraints from the different research fields, and to investigate if and how the different views on mantle flow can be reconciled with the currently available data.

This course is designed to acquaint students with a variety of approaches to the past used by historians writing in the twentieth century. The books we read have all made significant contributions to their respective sub-fields and have been selected to give as wide a coverage in both field and methodology as possible in one semester's worth of reading. We examine how historians conceive of their object of study, how they use primary sources as a basis for their accounts, how they structure the narrative and analytic discussion of their topic, and what are the advantages and drawbacks of their various approaches.

This seminar will explore the purposes and development of Technology Roadmaps for systematically mapping out possible development paths for various technological domains and the industries that build on them. Data of importance for such roadmaps include rates of innovation, key bottlenecks, physical limitations, improvement trendlines, corporate intent, and value chain and industry evolutionary paths. The course will build on ongoing work on the MIT Communications Technology Roadmap project, but will explore other domains selected from Nanotechnology, Bio-informatics, Geno/Proteino/Celleomics, Neurotechnology, Imaging & Diagnostics, etc. Thesis and Special Project opportunities will be offered.

This course is a seminar in topology. The main mathematical goal is to learn about the fundamental group, homology and cohomology. The main non-mathematical goal is to obtain experience giving math talks.

This seminar applies a systems perspective to understand health care delivery today, its stakeholders and problems as well as opportunities. Students are introduced to the 'systems perspective' that has been used successfully in other industries, and will address the introduction of new processes, technologies and strategies to improve overall health outcomes. Students are assigned to teams to work on a semester‐long group project, in collaboration with staff of a nearby Boston hospital.

This course focuses on evolution of contemporary politics and economics. The subject is divided into four parts:

1. Context: historical and strategic perspectives, theoretical issues, and sources and forms of conflict;
2. Continuity: detailed analysis conflicts systems and their persistence, as well as regional competition and recent wars – focusing on specific countries and cases;
3. Complexity: highlighting situation specific strategic gains and losses; and
4. Convergence: focusing future configurations of conflict and cooperation.

Throughout the course, special attention is given to sources and transformations of power, population dynamics and migration, resources and energy, as well as implications of technological change.

This course focuses on evolution of contemporary politics and economics. The subject is divided into four parts:

1. Context: historical and strategic perspectives, theoretical issues, and sources and forms of conflict;
2. Continuity: detailed analysis conflicts systems and their persistence, as well as regional competition and recent wars – focusing on specific countries and cases;
3. Complexity: highlighting situation specific strategic gains and losses; and
4. Convergence: focusing future configurations of conflict and cooperation.

Throughout the course, special attention is given to sources and transformations of power, population dynamics and migration, resources and energy, as well as implications of technological change.

This course uses lectures and discussion to introduce the range of topics relevant to plasma physics and fusion engineering. An introductory discussion of the economic and ecological motivation for the development of fusion power is also presented. Contemporary magnetic confinement schemes, theoretical questions, and engineering considerations are presented by expert guest lecturers. Students enrolled in the course also tour the Plasma Science and Fusion Center experimental facilities.

This course uses lectures and discussion to introduce the range of topics relevant to plasma physics and fusion engineering. An introductory discussion of the economic and ecological motivation for the development of fusion power is also presented. Contemporary magnetic confinement schemes, theoretical questions, and engineering considerations are presented by expert guest lecturers. Students enrolled in the course also tour the Plasma Science and Fusion Center experimental facilities.

This course provides an introduction to important philosophical questions about the mind, specifically those that are intimately connected with contemporary psychology and neuroscience. Are our concepts innate, or are they acquired by experience? (And what does it even mean to call a concept 'innate'?) Are 'mental images' pictures in the head? Is color in the mind or in the world? Is the mind nothing more than the brain? Can there be a science of consciousness? The course will include guest lectures by Professors.

This course explores the basis of electronic sensing of our world and how we then use these measures to change it.

This course explores photography as a disciplined way of seeing or investigating urban landscapes, and expressing ideas. Readings, observations, and photographs form the basis of discussions on light, detail, place, poetics, narrative, and how photography can inform design and planning.

The current version of the class website for the course can be found here: Sensing Place: Photography as Inquiry.

In this course, we will take you on a virtual journey covering different Earth observation tools. In the course modules, we cover the most crucial measurement tools for solid Earth, the atmosphere, and the biosphere. Our experts will give you first-hand insights why, where, and how those techniques are applied and they will show you how sensors work in space, on aircrafts, and on the ground.

You will be given insights on how you can use data from various sensors to better understand our living planet and how it changes. Together with your fellow learners all over the world, you will conduct joined experiments that demonstrate, how easy it is to sense the Earth’s environment. On top of that, world-renowned experts will be interviewed - telling you why they think it is so important that we study our planet.

Join us and let’s sense planet Earth together!

Global warming. Rising sea levels. Droughts. Flooding. The melting of the polar ice caps.

Join us, when we discover how continental water and ice masses are measured and monitored through remote sensing. Our experts give you first-hand insights how water and mass transport can be traced, and how this relates to the complex processes in the Earth‘s system.

Together with your fellow learners you will assess and evaluate statements made in relation to climate change. This will prepare you to make evidence-based decisions for a sustainable future.

Join us and let’s sense planet Earth together!

This course is a broad introduction to a host of sensor technologies, illustrated by applications drawn from human-computer interfaces and ubiquitous computing. After extensively reviewing electronics for sensor signal conditioning, the lectures cover the principles and operation of a variety of sensor architectures and modalities, including pressure, strain, displacement, proximity, thermal, electric and magnetic field, optical, acoustic, RF, inertial, and bioelectric. Simple sensor processing algorithms and wired and wireless network standards are also discussed. Students are required to complete written assignments, a set of laboratories, and a final project.

This course examines the neural bases of sensory perception. The focus is on physiological and anatomical studies of the mammalian nervous system as well as behavioral studies of animals and humans. Topics include visual pattern, color and depth perception, auditory responses and sound localization, and somatosensory perception.