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191 - 200 of 287 results for: CSI::certificate

MATSCI 156: Solar Cells, Fuel Cells, and Batteries: Materials for the Energy Solution

This course introduces students to emerging technological solutions to address the pressing energy demands of the world. It is motivated by discussions of the scale of global energy usage and requirements for possible solutions; however, the primary focus will be on the fundamental physics and chemistry of solar cells, fuel cells, and batteries from a materials science perspective. Students will learn about operating principles and performance, economic, and ethical considerations from the ideal device to the installed system. The promise of materials research for providing next generation solutions will be highlighted by guest speakers developing innovative energy technologies. Undergraduates register in 156 for 4 units; graduates register in 256 for 3 units. Prerequisites: Undergraduate coursework in thermodynamics (e.g., MATSCI 144, ME 30) and electromagnetism (e.g., PHYSICS 23/43).
Terms: Spr | Units: 3-4 | UG Reqs: GER:DB-EngrAppSci
Instructors: Chen, E. (PI)

ME 206A: Design for Extreme Affordability

Design for Extreme Affordability (fondly called Extreme) is a two-quarter course offered by the d.school through the School of Engineering and the Graduate School of Business. This multidisciplinary project-based experience creates an enabling environment in which students learn to design products and services that will change the lives of the world's poorest citizens. Students work directly with course partners on real world problems, the culmination of which is actual implementation and real impact. Topics include design thinking, product and service design, rapid prototype engineering and testing, business modelling, social entrepreneurship, team dynamics, impact measurement, operations planning and ethics. Possibility to travel overseas during spring break. Previous projects include d.light, Driptech, Earthenable, Embrace, the Lotus Pump, MiracleBrace, Noora Health and Sanku. Periodic design reviews; Final course presentation and expo; industry and adviser interaction. Limited enrollment via application. Must sign up for ME206A and ME206B. See extreme.stanford.edu
Terms: Win | Units: 4

ME 206B: Design for Extreme Affordability

Design for Extreme Affordability (fondly called Extreme) is a two-quarter course offered by the d.school through the School of Engineering and the Graduate School of Business. This multidisciplinary project-based experience creates an enabling environment in which students learn to design products and services that will change the lives of the world's poorest citizens. Students work directly with course partners on real world problems, the culmination of which is actual implementation and real impact. Topics include design thinking, product and service design, rapid prototype engineering and testing, business modelling, social entrepreneurship, team dynamics, impact measurement, operations planning and ethics. Possibility to travel overseas during spring break. Previous projects include d.light, Driptech, Earthenable, Embrace, the Lotus Pump, MiracleBrace, Noora Health and Sanku. Periodic design reviews; Final course presentation and expo; industry and adviser interaction. Limited enrollment via application. Must sign up for ME206A and ME206B. See extreme.stanford.edu. Cardinal Course certified by the Haas Center
Terms: Spr | Units: 4

ME 243: Designing Emotion: for Reactive Car Interfaces

Students learn to define emotions as physiology, expression, and private experience using the automobile and shared space. Explores the meaning and impact of personal and user car experience. Reflective, narrative, and socio-cognitive techniques serve to make sense of mobility experiences; replay memories; examine engagement; understand user interviews. This course celebrates car fascination and leads the student through finding and telling the car experience through discussion, ethnographic research, interviews, and diverse individual and collaborative narrative methods-verbal, non-verbal, and in car experiences. Methods draw from socio-cognitive psychology, design thinking, and fine art, and are applied to the car or mobility experience. Course culminates in a final individual narrative presentation and group project demonstration. Class size limited to 18.
Terms: Aut | Units: 1-3 | Repeatable 2 times (up to 3 units total)
Instructors: Karanian, B. (PI)

ME 302B: The Future of the Automobile- Driver Assistance and Automated Driving

This course provides a holistic overview over the field of vehicle automation. The course starts with the history of vehicle automation and then introduces key terminology and taxonomy. Guest lecturers present the legal and policy aspects of vehicle automation both on the federal and state level. Then, the state of the art in vehicle automation is provided. This includes sensor and actuator technology as well as the driver assistance technology in cars today. Finally, the technology currently being developed for future highly and fully automated vehicles is described, including a high-level introduction of the software and algorithms used as well as HMI and system aspects. Students are asking to work in groups on a current topic related to vehicle automation and present their findings in the final two classes in a short presentation.
Terms: Win | Units: 1 | Repeatable 2 times (up to 2 units total)
Instructors: Becker, J. (PI)

ME 368A: Biodesign Innovation: Needs Finding and Concept Creation (BIOE 374A, MED 272A)

In this two-quarter course series ( BIOE 374A/B, MED 272A/B, ME 368A/B, OIT 384/5), multidisciplinary student teams identify real-world unmet healthcare needs, invent new health technologies to address them, and plan for their implementation into patient care. During the first quarter (winter), students select and characterize an important unmet healthcare problem, validate it through primary interviews and secondary research, and then brainstorm and screen initial technology-based solutions. In the second quarter (spring), teams select a lead solution and move it toward the market through prototyping, technical re-risking, strategies to address healthcare-specific requirements (regulation, reimbursement), and business planning. Final presentations in winter and spring are made to a panel of prominent health technology experts and/or investors. Class sessions include faculty-led instruction and case studies, coaching sessions by industry specialists, expert guest lecturers, and int more »
In this two-quarter course series ( BIOE 374A/B, MED 272A/B, ME 368A/B, OIT 384/5), multidisciplinary student teams identify real-world unmet healthcare needs, invent new health technologies to address them, and plan for their implementation into patient care. During the first quarter (winter), students select and characterize an important unmet healthcare problem, validate it through primary interviews and secondary research, and then brainstorm and screen initial technology-based solutions. In the second quarter (spring), teams select a lead solution and move it toward the market through prototyping, technical re-risking, strategies to address healthcare-specific requirements (regulation, reimbursement), and business planning. Final presentations in winter and spring are made to a panel of prominent health technology experts and/or investors. Class sessions include faculty-led instruction and case studies, coaching sessions by industry specialists, expert guest lecturers, and interactive team meetings. Enrollment is by application only, and students are required to participate in both quarters of the course. Visit http://biodesign.stanford.edu/programs/stanford-courses/biodesign-innovation.html to access the application, examples of past projects, and student testimonials. More information about Stanford Biodesign, which has led to the creation of 50 venture-backed healthcare companies and has helped hundreds of student launch health technology careers, can be found at http://biodesign.stanford.edu/.
Terms: Win | Units: 4

ME 368B: Biodesign Innovation: Concept Development and Implementation (BIOE 374B, MED 272B)

In this two-quarter course, multidisciplinary teams identify real unmet healthcare needs, invent health technologies to address them, and plan for their implementation into patient care. In second quarter, teams select a lead solution to advance through technical prototyping, strategies to address healthcare-specific requirements (IP, regulation, reimbursement), and business planning. Class sessions include faculty-led instruction, case studies, coaching sessions by experts, guest lecturers, and interactive team meetings. Enrollment is by application. Students are required to take both quarters of the course.
Terms: Spr | Units: 4 | Repeatable 2 times (up to 8 units total)

MED 157: Foundations for Community Health Engagement

Open to undergraduate, graduate, and MD students. Examination and exploration of community health principles and their application at the local level. Designed to prepare students to make substantive contributions in a variety of community health settings (e.g. clinics, government agencies, non-profit organization, advocacy groups). Topics include community health assessment; health disparities; health promotion and disease prevention; strategies for working with diverse, low-income, and underserved populations; and principles of ethical and effective community engagement.
Terms: Spr | Units: 3 | UG Reqs: WAY-SI, WAY-EDP
Instructors: Heaney, C. (PI)

MED 200: Primary Care Presentations

This course is a lecture series offered during the winter quarter. The aim of this seminar is to allow medical students to experience the mindset of primary care physicians in real time. Classes feature presentations of patient cases submitted by Stanford faculty. Faculty presenters are provided with the diagnostic information for the cases in a sequential manner during and not in advance of each class, allowing students to learn from the thought process of physicians in real time as they put together the differential diagnosis, interpret diagnostic information, deliberate treatment and management options, and discuss other thoughts about the cases.
Terms: Win | Units: 1

MED 212: Methods for Health Care Delivery Innovation, Implementation and Evaluation (CHPR 212, HRP 218)

Preference given to postgraduate fellows and graduate students.Focus is on implementation science and evaluation of health care delivery innovations. Topics include implementation science theory, frameworks, and measurement principles; qualitative and quantitative approaches to designing and evaluating new health care models; hybrid design trials that simultaneously evaluate implementation and effectiveness; distinction between quality improvement and research, and implications for regulatory requirements and publication; and grant-writing strategies for implementation science and evaluation. Students will develop a mock (or actual) grant proposal to conduct a needs assessment or evaluate a Stanford/VA/community intervention, incorporating concepts, frameworks, and methods discussed in class. Priority for enrollment for CHPR 212 will be given to CHPR master's students.
Terms: Win | Units: 2
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