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1 - 10 of 116 results for: CEE

CEE 31: Accessing Architecture Through Drawing

Preference to Architectural Design and CEE majors; others by consent of instructor. Drawing architecture to probe the intricacies and subtleties that characterize contemporary buildings. How to dissect buildings and appreciate the formal elements of a building, including scale, shape, proportion, colors and materials, and the problem solving reflected in the design. Students construct conventional architectural drawings, such as plans, elevations, and perspectives. Limited enrollment.
Terms: Aut, Win | Units: 5 | UG Reqs: GER:DB-EngrAppSci, WAY-CE
Instructors: Wood, E. (PI)

CEE 32A: Psychology of Architecture

This course argues that architecture often neglects the interdisciplinary investigation of our internal psychological experience and the way it impacts our creation of space. How does our inner life influence external design? How are we impacted emotionally, physically, psychologically by the spaces we inhabit day to day? How might we intentionally imbue personal and public spaces with specific emotions? This seminar serves as a call to action for students interested in approaching architecture with a holistic understanding of the emotional impact of space. Sample topics addressed will include: conscious vs. unconscious design; the ego of architecture; psycho-spatial perspectives; ideas of home; integral/holistic architecture; phenomenology of inner and outer spaces; exploring archetypal architecture; and translating emotion through environment.
Terms: Win | Units: 3 | UG Reqs: WAY-A-II, WAY-CE

CEE 32B: Design Theory

This seminar focuses on the key themes, histories, and methods of architectural theory -- a form of architectural practice that establishes the aims and philosophies of architecture. Architectural theory is primarily written, but it also incorporates drawing, photography, film, and other media. nnOne of the distinctive features of modern and contemporary architecture is its pronounced use of theory to articulate its aims. One might argue that modern architecture is modern because of its incorporation of theory. This course focuses on those early-modern, modern, and late-modern writings that have been and remain entangled with contemporary architectural thought and design practice. nnRather than examine the development of modern architectural theory chronologically, it is explored architectural through thematic topics. These themes enable the student to understand how certain architectural theoretical concepts endure, are transformed, and can be furthered through his/her own explorations.
Terms: Aut, Win | Units: 4 | UG Reqs: GER:DB-Hum, WAY-A-II
Instructors: Beischer, T. (PI)

CEE 64: Air Pollution and Global Warming: History, Science, and Solutions (CEE 263D)

Survey of Survey of air pollution and global warming and their renewable energy solutions. Topics: evolution of the Earth's atmosphere, history of discovery of chemicals in the air, bases and particles in urban smog, visibility, indoor air pollution, acid rain, stratospheric and Antarctic ozone loss, the historic climate record, causes and effects of global warming, impacts of energy systems on pollution and climate, renewable energy solutions to air pollution and global warming. UG Reqs: GER: DBNatSci
Terms: Win | Units: 3 | UG Reqs: GER: DB-NatSci, WAY-SMA
Instructors: Jacobson, M. (PI)

CEE 70: Environmental Science and Technology (ENGR 90)

Introduction to environmental quality and the technical background necessary for understanding environmental issues, controlling environmental degradation, and preserving air and water quality. Material balance concepts for tracking substances in the environmental and engineering systems.
Terms: Win, Sum | Units: 3 | UG Reqs: GER:DB-EngrAppSci, WAY-AQR
Instructors: Kopperud, R. (PI)

CEE 80N: Engineering the Built Environment: An Introduction to Structural Engineering

In this seminar, students will be introduced to the history of modern bridges, buildings and other large-scale structures. Classes will include presentations on transformations in structural design inspired by the development of new materials, increased understanding of hazardous overloads and awareness of environmental impacts. Basic principles of structural engineering and how to calculate material efficiency and structural safety of structural forms will be taught using case studies. The course will include a field trip to a Bay Area large-scale structure, hands-on experience building a tower and computational modeling of bridges, and a paper and presentation on a structure or structural form of interest to the student. The goal of this course is for students to develop an understanding and appreciation of modern structures, influences that have led to new forms, and the impact of structural design on society and the environment. Students from all backgrounds are welcome.
Terms: Win | Units: 3 | UG Reqs: WAY-AQR

CEE 101A: Mechanics of Materials

Introduction to beam and column theory. Normal stress and strain in beams under various loading conditions; shear stress and shear flow; deflections of determinate and indeterminate beams; analysis of column buckling; structural loads in design; strength and serviceability criteria. Lab experiments. Prerequisites: ENGR 14.
Terms: Win | Units: 4 | UG Reqs: GER:DB-EngrAppSci
Instructors: Linder, C. (PI)

CEE 102: Legal Principles in Design, Construction, and Project Delivery

Introduction to the key legal principles affecting design, construction and the delivery of infrastructure projects. The course begins with an introduction to the structure of law, including principles of contract, negligence, professional responsibility, intellectual property, land use and environmental law, then draws on these concepts to examine current and developing means of project delivery.
Terms: Win | Units: 3
Instructors: Ashcraft, H. (PI)

CEE 107R: E3: Extreme Energy Efficiency (CEE 207R)

Be part of a unique and intense six day course about extreme energy efficiency taking place during Spring Break 2018 at Rocky Mountain Institute's Innovation Center in Basalt, Colorado! The course will focus on efficiency techniques' design, performance, choice, evolution, integration, barrier-busting, profitable business-led implementation, and implications for energy supply, competitive success, environment, development, security, etc. Examples will span very diverse sectors, applications, issues, and disciplines, with each day covering a different energy theme: buildings, transportation, industry, and implementation and implications, including renewable energy synergy and integration. Solid technical grounding and acquaintance with basic economics and business concepts will both be helpful. Rocky Mountain Institute (RMI) will design a series of lectures, exercises, and interactive activities synthesizing integrative design principles. Students will be introduced to Factor 10 Engineering, the approach for optimizing the whole system for multiple benefits. Students will work closely and interactively with RMI staff including Amory Lovins, cofounder and Chief Scientist of Rocky Mountain Institute (RMI). Exercises will illuminate challenges RMI has faced and solutions it has created in real-world design. Students will explore clean-sheet solutions that meet end-use demands and optimize whole-system resource efficiency, often with expanding rather than diminishing returns to investments, i.e. making big savings cheaper than small ones. Students will meet as a class once during winter quarter to discuss preparation and spring break logistics. Students must pay for their own travel to and from Basalt, CO (~$400-$600). Course will take place Sunday, March 25 - Friday, March 30. Lodging and food will be covered during the course. Must apply - instructor approval required. All backgrounds and disciplines, both undergraduate and graduate, are welcome to apply. Prerequisite - completion of one of the following courses is required: CEE 107A, CEE 207A, Earthsys 103, CEE 107S, CEE 207S, CEE 176A, CEE 176B. Contact Diana Ginnebaugh at moongdes@stanford.edu for an application. Course website: https://web.stanford.edu/class/cee207r/
Terms: Aut, Win | Units: 2
Instructors: Gragg, D. (PI)

CEE 112A: Industry Applications of Virtual Design & Construction

Building upon the concept of VDC Scorecard, CEE 112A/212A investigates in the management of Virtual Design and Construction (VDC) programs and projects in the building industry. Interacting with experts and professionals in real estate, architecture, engineering, construction and technology providers, students will learn from the industry applications of Building Information Modeling and its relationship with Integrated Project Delivery, Sustainable Design and Construction. Students will conduct case studies to evaluate the maturity of VDC planning, adoption, technology and performance in practice. Students taking 3 or 4 units will be paired up with independent research or case study projects on the industry applications of VDC. No prerequisite. See CEE112B/212B in the Winter Quarter and CEE 112C/212C in the Spring Quarter.
Terms: Win, Spr | Units: 2-4
Instructors: Kam, C. (PI)
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