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171 - 180 of 258 results for: all courses

LINGUIST 47N: Languages, Dialects, Speakers

Preference to freshmen. Variation and change in languages from around the world; the roots, historical development, and linguistic and social structures of variation; how languages differ from one another and how issues in linguistics connect to other social and cultural issues; the systematic study of language.
Terms: Spr | Units: 3 | UG Reqs: GER:DB-SocSci
Instructors: Anttila, A. (PI)

LINGUIST 52N: Spoken Sexuality: Language and the Social Construction of Sexuality (FEMGEN 52N)

The many ways language is used in the construction of sexuality and sexual identity. How language is used as a resource for performing and perceiving sexual identity. Drawing on linguistic analyses of pronunciation, word choice, and grammar, questions such as: Is there a gay accent? Why isn't there a lesbian accent? How do transgendered people modify their linguistic behavior when transitioning? How are unmarked (heterosexual) identities linguistically constructed? Sexuality as an issue of identity, as well as of desire. Iconic relations between elements of language such as breathy voice quality and high pitch, and aspects of desire such as arousal and excitement. How language encodes ideologies about sexuality; how language is used to talk about sexuality in public discourses about gay marriage and bullying, as well as in personal narratives of coming out. How language encodes dominant ideologies about sexuality, evident in labels for sexual minorities as well as terminology for sex acts. Discussions of readings, explorations of how sexuality is portrayed in popular media, and analyses of primary data. Final research paper on a topic of student choice.
Terms: Win | Units: 3
Instructors: Podesva, R. (PI)

LINGUIST 83Q: Translation

Preference to sophomores. What is a translation? The increased need for translations in the modern world due to factors such as tourism and terrorism, localization and globalization, diplomacy and treaties, law and religion, and literature and science. How to meet this need; different kinds of translation for different purposes; what makes one translation better than another; why some texts are more difficult to translate than others. Can some of this work be done by machines? Are there things that cannot be said in some languages?
Terms: Aut | Units: 3 | UG Reqs: GER:DB-SocSci
Instructors: Kay, M. (PI)

MATH 80Q: Capillary Surfaces: Explored and Unexplored Territory

Preference to sophomores. Capillary surfaces: the interfaces between fluids that are adjacent to each other and do not mix. Recently discovered phenomena, predicted mathematically and subsequently confirmed by experiments, some done in space shuttles. Interested students may participate in ongoing investigations with affinity between mathematics and physics.
Terms: Spr | Units: 3 | UG Reqs: WAY-SMA, WAY-FR
Instructors: Finn, R. (PI)

MATH 87Q: Mathematics of Knots, Braids, Links, and Tangles

Preference to sophomores. Types of knots and how knots can be distinguished from one another by means of numerical or polynomial invariants. The geometry and algebra of braids, including their relationships to knots. Topology of surfaces. Brief summary of applications to biology, chemistry, and physics.
Terms: Spr | Units: 3 | UG Reqs: WAY-FR

MATSCI 82N: Science of the Impossible

Imagine a world where cancer is cured with light, objects can be made invisible, and teleportation is allowed through space and time. The future once envisioned by science fiction writers is now becoming a reality, thanks to advances in materials science and engineering. This seminar will explore 'impossible' technologies - those that have shaped our past and those that promise to revolutionize the future. Attention will be given to both the science and the societal impact of these technologies. We will begin by investigating breakthroughs from the 20th century that seemed impossible in the early 1900s, such as the invention of integrated circuits and the discovery of chemotherapy. We will then discuss the scientific breakthroughs that enabled modern 'impossible' science, such as photodynamic cancer therapeutics, invisibility, and psychokinesis through advanced mind-machine interfaces. Lastly, we will explore technologies currently perceived as completely impossible and brainstorm the breakthroughs needed to make such science fiction a reality. The course will include introductory lectures and in-depth conversations based on readings. Students will also be given the opportunity to lead class discussions on a relevant 'impossible science' topic of their choosing.
Terms: Spr | Units: 3
Instructors: Dionne, J. (PI)

MATSCI 159Q: Japanese Companies and Japanese Society (ENGR 159Q)

Preference to sophomores. The structure of a Japanese company from the point of view of Japanese society. Visiting researchers from Japanese companies give presentations on their research enterprise. The Japanese research ethic. The home campus equivalent of a Kyoto SCTI course.
Terms: Spr | Units: 3 | UG Reqs: GER:DB-SocSci
Instructors: Sinclair, R. (PI)

ME 10N: Form and Function of Animal Skeletons (BIOE 10N)

Preference to freshmen. The biomechanics and mechanobiology of the musculoskeletal system in human beings and other vertebrates on the level of the whole organism, organ systems, tissues, and cell biology. Field trips to labs.
Terms: Win | Units: 3 | UG Reqs: GER:DB-EngrAppSci
Instructors: Carter, D. (PI)

ME 13N: The Great Principle of Similitude

The rules of dimensional analysis were formulated by Isaac Newton, who called it The Great Principle of Similitude. On its surface, it is a look at the relationships between physical quantities by exploring their basic units. In fact, it is a powerful and formalized method to analyze complex physical phenomena, including those for which we cannot pose, much less solve, governing equations. Valuable to engineers and scientists as it helps perform back-of-the- envelope estimates and derive scaling laws for the design of machines and processes, the principle has been applied to the study of complex phenomena in biology, aerodynamics, chemistry, social science, astrophysics, and economics. Focus is on tools to perform such analyses. Examples include estimating the running speed of a hungry velociraptor, the probability of serious injury in a car accident, the cost of submarines, and the energy released by an atomic weapon. Students identify problems in everyday life and/or current world events to analyze with this tool.
Terms: Aut | Units: 3
Instructors: Santiago, J. (PI)

ME 16N: Energy & The Industrial Revolution - Past, Present & Future

When you flip a light switch, or drive to your neighborhood grocery store or do a Google search, it is easy to forget that we receive the benefit of 250 years of industrial revolution, which has been arguably the most remarkable period of human history. This revolution has resulted in exponential growth in the world¿s economy as well as unprecedented prosperity and improvements in our quality of life. The industrial revolution has been largely about how we sourced, distributed and used energy. It was and continues to be predominantly based on fossil energy. But the impact of our traditional energy sources on climate change is one of the most daunting issues of the 21st century because it will affect the world as a whole - the 7-10 billion people, businesses, nations, ecosystems. nnThe choice that our society is asked to make is often posed as follows: Should we continue our exponential economic growth based on fossil fuels and ignore the environment, or should we reduce our greenhouse gas emissions at the cost of our economic growth? This is a false choice because it is based on extrapolating the past. It does not account for the capacity for innovations in technology, finance and business to create sustainable energy future, one that allows the economy and our environment to be mutually inclusive. In short, we need a new industrial revolution. nnThis seminar course will: (a) provide a view of the current energy landscape and the magnitude of the challenge; (b) discuss some techno-economic trends that we are currently witnessing; and (c) identify opportunities to innovate in technology, finance and business that could create the foundations for a new industrial revolution.
Terms: Aut | Units: 3
Instructors: Majumdar, A. (PI)
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