More advanced treatment of biochemical mechanisms that underlie biological processes. Emphasis on experimental methods used to unravel these processes, and how these processes fit into the cellular context and coordinate regulation of these processes. Topics include macromolecular machines for energy and force transduction, regulation of biosynthetic and degradative pathways, and structure and function of nucleic acids.

MIT researcher Deb Roy wanted to understand how his infant son learned language -- so he wired up his house with videocameras to catch every moment (with exceptions) of his son's life, then parsed 90,000 hours of home video to watch "gaaaa" slowly turn into "water." Astonishing, data-rich research with deep implications for how we learn. Deb Roy studies how children learn language, and designs machines that learn to communicate in human-like ways. On sabbatical from MIT Media Lab, he's working with the AI company Bluefin Labs. A quiz, thought provoking question, and links for further study are provided to create a lesson around the 20-minute video. Educators may use the platform to easily "Flip" or create their own lesson for use with their students of any age or level.

Design Fabrication is an introductory course in the field of advanced computing, prototyping and building fabrication. The class is focused on the relationship between design, various forms of computer modeling both explicit and generative and the physical representation of information using rapid prototyping devices.

This class serves as an introductory subject in advanced computing, rapid prototyping, and CAD/CAM fabrication for architects. It focuses on the relationship between design and various forms of computer modeling as input, and CAD/CAM tools as output material. It presents the process of design and construction using CAD files introduced by the office of Gehry Partners during the construction of the Guggenheim Museum in Bilbao, Spain. It is taught in phases starting with rapid prototyping and ending with digital mockups of building components fabricated from CAD files on a one-to-one scale.

Students will review different types of equations by playing Math-O.

Finite element analysis is now widely used for solving complex static and dynamic problems encountered in engineering and the sciences. In these two video courses, Professor K. J. Bathe, a researcher of world renown in the field of finite element analysis, teaches the basic principles used for effective finite element analysis, describes the general assumptions, and discusses the implementation of finite element procedures for linear and nonlinear analyses. These videos were produced in 1982 and 1986 by the MIT Center for Advanced Engineering Study.

Inspired by the work of the architect Antoni Gaudi, this research workshop will explore three-dimensional problems in the static equilibrium of structural systems. Through an interdisciplinary collaboration between computer science and architecture, we will develop design tools for determining the form of three-dimensional structural systems under a variety of loads. The goal of the workshop is to develop real-time design and analysis tools which will be useful to architects and engineers in the form-finding of efficient three-dimensional structural systems.

" This course will introduce students to architectural design and computation through the use of computer modeling, rendering and digital fabrication. The course focuses on teaching architectural design with CAD drawing, 3-D modeling, rendering and rapid prototyping. Students will be required to build computer models that will lead to a full package of architectural explorations with computers. Each semester we will explore the design process of a particular building type and building material. The course also investigates a few design processes of selected architects. The course is critical of design principles and building production methods. Student Assignments and Labs are graded based on the quality of design, representation and constructability. Great design input is always encouraged."

Explores the role of computer visualization as a representational medium. Visualization is widely used in scientific, engineering, and design disciplines to help people understand complex phenomena and constructs. The key intellectual challenge is to develop the right visual metaphors for conveying information in the most effective way. Through programming projects and applications work, real and imaginary environments are constructed, probed, and displayed. Also covers the relevant computer graphics methods and data representations. Required of Course IV majors. This course will introduce students to architectural design and computation through the use of computer modeling, rendering and digital fabrication. The course focuses on teaching architectural design with CAD drawing, modeling, rendering and rapid prototyping. Students will be required to build computer models that will lead to a full package of architectural explorations within a computational environment. Each semester will explore a particular historical period in architecture and the work of a selected architect.

This course introduces students to architectural design and computation through the use of computer modeling, rendering, and digital fabrication. The focus is on the exploration of space and place-making through the use of computer rendering and design construction and fabrication. Students design a small building using computer models leading to a full package of physical and virtual materials, from computer generated drawings to rapid, prototyped models.

Basic concepts of computer modeling in science and engineering using discrete particle systems and continuum fields. Techniques and software for statistical sampling, simulation, data analysis and visualization. Use of statistical, quantum chemical, molecular dynamics, Monte Carlo, mesoscale and continuum methods to study fundamental physical phenomena encountered in the fields of computational physics, chemistry, mechanics, materials science, biology, and applied mathematics. Applications drawn from a range of disciplines to build a broad-based understanding of complex structures and interactions in problems where simulation is on equal-footing with theory and experiment. Term project allows development of individual interest. Student mentoring by a coordinated team of participating faculty from across the Institute.

Experimental and theoretical aspects of chemical reaction kinetics, including transition-state theories, molecular beam scattering, classical techniques, quantum and statistical mechanical estimation of rate constants, pressure-dependence and chemical activation, modeling complex reacting mixtures, and uncertainty/ sensitivity analyses. Reactions in the gas phase, liquid phase, and on surfaces are discussed with examples drawn from atmospheric, combustion, industrial, catalytic, and biological chemistry.

In the Fall 1998 Edition of the Natural Inquirer you will learn about Dogwood Antracnose, land use, outdoor recreation, computer modeling, soil fumigation, and the Red-cockaded Woodpecker.

Do you like to discover new things? Are you interested in learning about nature? Then the Natural Inquirer is for you! This journal is full of new information on the natural environment that we call the Rocky Mountains. In this Natural Inquirer, you will learn how father owls feed their young, the dangers that songbirds sometimes face and how beetles stay warm during the winter. Find out how avalanches are formed, whether trout always pick the same place to swim in a stream and how a computer can be used to predict soil erosion! Have fun learning all about the Rocky Mountains!