Results for ENGR

Introduction to engineering analysis using the principles of engineering solid mechanics. Builds on the math and physical reasoning concepts in Physics 41 to develop skills in evaluation of engineered systems across a variety of fields. Foundational ideas for more advanced solid mechanics courses such as ME80 or CEE101A. Interactive lecture sessions focused on mathematical application of key concepts, with weekly complementary lab session on testing and designing systems that embody these concepts. Limited enrollment, subject to instructor approval. Pre-requisite: Physics 41. When signing up for this course make sure to sign up both for the lecture and for a Discussion Section.

Overview of chemical engineering through discussion and engineering analysis of physical and chemical processes. Topics: overall staged separations, material and energy balances, concepts of rate processes, energy and mass transport, and kinetics of chemical reactions. Applications of these concepts to areas of current technological importance: biotechnology, energy, production of chemicals, materials processing, and purification. Prerequisite: CHEM 31.

Is a hands-on class where students learn to make stuff. Through the process of building, you are introduced to the basic areas of EE. Students build a "useless box" and learn about circuits, feedback, and programming hardware, a light display for your desk and bike and learn about coding, transforms, and LEDs, a solar charger and an EKG machine and learn about power, noise, feedback, more circuits, and safety. And you get to keep the toys you build. Prerequisite: CS 106A.

Materials structure, bonding and atomic arrangements leading to their properties and applications. Topics include electronic, thermal and mechanical behavior; emphasizing energy related materials and challenges.

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.

The theory and practice of teaching public speaking and presentation development. Lectures/discussions on developing an instructional plan, using audiovisual equipment for instruction, devising tutoring techniques, and teaching delivery, organization, audience analysis, visual aids, and unique speaking situations. Weekly practice speaking. Students serve as apprentice speech tutors. Those completing course may become paid speech instructors in the Technical Communications Program. Prerequisite: consent of instructor.

Priority to Engineering students. Introduction to speaking activities, from impromptu talks to carefully rehearsed formal professional presentations. How to organize and write speeches, analyze audiences, create and use visual aids, combat nervousness, and deliver informative and persuasive speeches effectively. Weekly class practice, rehearsals in one-on-one tutorials, videotaped feedback. Limited enrollment.

This course applies the mindsets and innovation principles of design thinking to the "wicked problem" of designing your life and vocation. The course introduces design thinking processes through application: students practice awareness and empathy, define areas of life and work on which hey want to work, ideate about ways to move forward, try small prototypes, and test their assumptions. The course is highly interactive. The course will include brief readings, writing, reflections, and in-class exercises. Expect to practice ideation and prototyping methodologies, decision making practices and to participate in hands on activities in pairs, trios, and small groups. Also includes roleplaying, assigned conversations with off campus professionals, guest speakers, and individual mentoring and coaching. It will conclude with creation of 3 versions of the next 5 years and prototype ideas to begin making those futures a reality. Open to juniors, seniors and 5th year coterms, all majors. All enrolled and waitlisted students should attend class on day 1 for admission. Additional course information at http://www.designingyourlife.org.

DYS uses a Design Thinking approach to help Freshmen and Sophomores learn practical tools and ideas to make the most of their Stanford experience. Topics include the purpose of college, major selection, educational and vocational wayfinding, and innovating college outcomes, explored through the design thinking process. This seminar class incorporates small group discussion, in-class activities, field exercises, personal reflection, and individual coaching. Expect ideation tools, storytelling practices, prototyping to discover more about yourself and possible paths forward. The course concludes with creation of multiple versions of what college might look like and how to make those ideas reality. All enrolled and waitlisted students should attend class on day 1 for admission. Additional course information at http://lifedesignlab.stanford.edu/dys.

Design of linear feedback control systems for command-following error, stability, and dynamic response specifications. Root-locus and frequency response design techniques. Examples from a variety of fields. Some use of computer aided design with MATLAB. Prerequisites: Dynamics systems (EE 102B or ME 161), and ordinary differential equations (CME 102 or Math 53). This course will include synchronous teaching sessions, but will be recorded to allow asynchronous participation

Seminar and student project course. Explores the medical, social, ethical, and technical challenges surrounding the design, development, and use of technologies that improve the lives of people with disabilities and older adults. Guest lecturers include engineers, designers, researchers, entrepreneurs, clinicians, and assistive technology users. Special activities include field trips to local facilities, an assistive technology faire, and a film screening. Students from any discipline are welcome to enroll. 3 units for students (juniors, seniors, and graduate students preferred) who pursue a team-based assistive technology project with a community partner - enrollment is limited to 27. 1 unit for seminar attendance only (CR/NC) or individual project (letter grade). Projects can be continued as independent study in Spring Quarter. See course website at http://engr110.stanford.edu. Designated a Cardinal Course by the Haas Center for Public Service.

Engineering topics in mass and energy transport in porous media relevant to energy systems. Mass, momentum and energy conservation equations in porous structures. Single phase and multiphase flow through porous media. Gas laws. Introduction to thermodynamics. Chemical, physical, and thermodynamic properties of liquids and gases in the subsurface.

How does the entrepreneurship process enable the creation and growth of high-impact enterprises? Why does entrepreneurial leadership matter even in a large organization or a non-profit venture? What are the differences between just an idea and true opportunity? How do entrepreneurs form teams and gather the resources necessary to create a successful startup? Mentor-guided projects focus on analyzing students' ideas, case studies allow for examining the nuances of innovation, research examines the entrepreneurial process, and expert guests allow for networking with Silicon Valley's world-class entrepreneurs and venture capitalists. For undergraduates of all majors with interest in startups the leverage breakthrough information, energy, medical and consumer technologies. No prerequisites. Limited Enrollment.

Principled Entrepreneurial Decisions examines how leaders tackle significant inflection points that occur in high-growth entrepreneurial companies. Students learn how to develop principles as a powerful tool to face tough situations that they will encounter in their lives and their chosen career. Cases and guest speakers discuss not only the business rationale for the decisions taken but also how their principles affected those decisions. A capstone project provides frameworks for students to develop their own set of principles. The teaching team brings its wealth of experience in both entrepreneurship and VC investing to the class. Limited enrollment. Admission by application: https://forms.gle/VU36jjGwmsK54CsK9

Analytical and numerical methods for solving ordinary differential equations arising in engineering applications are presented. For analytical methods students learn to solve linear and non-linear first order ODEs; linear second order ODEs; and Laplace transforms. Numerical methods using MATLAB programming tool kit are also introduced to solve various types of ODEs including: first and second order ODEs, higher order ODEs, systems of ODEs, initial and boundary value problems, finite differences, and multi-step methods. This also includes accuracy and linear stability analyses of various numerical algorithms which are essential tools for the modern engineer. This class is foundational for professional careers in engineering and as a preparation for more advanced classes at the undergraduate and graduate levels. Prerequisites: knowledge of single-variable calculus equivalent to the content of Math 19-21 (e.g., 5 on Calc BC, 4 on Calc BC with Math 21, 5 on Calc AB with Math 21). Placement diagnostic (recommendation non-binding) at: https://exploredegrees.stanford.edu/undergraduatedegreesandprograms/#aptext.

Probability: random variables, independence, and conditional probability; discrete and continuous distributions, moments, distributions of several random variables. Numerical simulation using Monte Carlo techniques. Topics in mathematical statistics: random sampling, point estimation, confidence intervals, hypothesis testing, non-parametric tests, regression and correlation analyses. Numerous applications in engineering, manufacturing, reliability and quality assurance, medicine, biology, and other fields. Prerequisite: CME100/ENGR154 or Math 51 or 52.

This discussion-rich course is for students to learn design thinking to more confidently navigate life and careers as members and allies of the Black community. This course will allow students to navigate identity while building community to uplift Black voices through design thinking tools to help leverage their experiences and gain a competitive edge. Students will gain a deeper understanding of intersectionality, how to create and cultivate alignment, and learn to effectively navigate life design schemas, ideas, and options.

Special studies, lab work, or reading under the direction of a faculty member. Often research experience opportunities exist in ongoing research projects. Students make arrangements with individual faculty and enroll in the section number corresponding to the particular faculty member. May be repeated for credit. Prerequisite: consent of instructor.

Additional problem solving practice for the calculus courses. Sections are designed to allow students to acquire a deeper understanding of calculus and its applications, work collaboratively, and develop a mastery of the material. Limited enrollment, permission of instructor required. Concurrent enrollment in MATH 19, 20, 52, or 53 required

Technical writing in science and engineering. Students produce a substantial document describing their research, methods, and results. Prerequisite: completion of freshman writing requirements; prior or concurrent in 2 units of research in the major department; and consent of instructor. WIM for select School of Engineering majors with permission from advisor.

Effective writing is key to academic and professional progress. 202S provides individualized writing instruction for students working on important writing projects such as dissertations, grant proposals, theses, journal articles, and teaching and research statements. The course consists of once weekly one-on-one conferences with lecturers from the Technical Communication Program. Students receive close attention to and detailed feedback on their writing to help them become more confident writers, hone their writing skills, and tackle any writing issues they may have. The TCP Director assigns each student to an instructor; meetings are scheduled by each instructor. No prerequisite. Grading: Satisfactory/No Credit. This course may be repeated for credit.

To be effective as an engineer or scientist, you must communicate your cutting-edge research and projects effectively to a broad range of audiences: your professors, your fellow students, your colleagues in the field, and sometimes the public. ENGR. 202W offers a collaborative environment in which you will hone your communication skills by writing and presenting about a project of your choosing and working on your CV/resume. ENGR202W is a practicum (supervised practical application) that helps you build toward a complete skillset for technical communication in the twenty-first century. Through interactive presentations and activities, group workshops, and individual conferences, you will learn best practices for communicating to academic and professional audiences for a range of purposes.

Priority to Engineering students. Introduction to speaking activities, from impromptu talks to carefully rehearsed formal professional presentations. How to organize and write speeches, analyze audiences, create and use visual aids, combat nervousness, and deliver informative and persuasive speeches effectively. Weekly class practice, rehearsals in one-on-one tutorials, videotaped feedback. Limited enrollment.

Seminar and student project course. Explores the medical, social, ethical, and technical challenges surrounding the design, development, and use of technologies that improve the lives of people with disabilities and older adults. Guest lecturers include engineers, designers, researchers, entrepreneurs, clinicians, and assistive technology users. Special activities include field trips to local facilities, an assistive technology faire, and a film screening. Students from any discipline are welcome to enroll. 3 units for students (juniors, seniors, and graduate students preferred) who pursue a team-based assistive technology project with a community partner - enrollment is limited to 27. 1 unit for seminar attendance only (CR/NC) or individual project (letter grade). Projects can be continued as independent study in Spring Quarter. See course website at http://engr110.stanford.edu. Designated a Cardinal Course by the Haas Center for Public Service.

This course investigates how culture and diversity shape who becomes an engineer, what problems get solved, and the quality of designs, technology, and products. As a course community, we consider how cultural beliefs about race, ethnicity, gender, sexuality, abilities, socioeconomic status, and other intersectional aspects of identity interact with beliefs about engineering, influence diversity in the field, and affect equity in engineering education and practice. We also explore how engineering cultures and environments respond to and change with individual and institutional agency. The course involves weekly presentations by scholars and engineers, readings, short writing assignments, small-group discussion, and hands-on, student-driven projects. Students can enroll in the course for 1 unit (lectures only), or 3 units (lectures+discussion+project). For 1 unit, students should sign up for Section 1 and Credit/No Credit grading, and for 3 units students should sign up for Section 2 and either the C/NC or Grade option.

Miniaturization technologies now have important roles in materials, mechanical, and biomedical engineering practice, in addition to being the foundation for information technology. This course will target an audience of first-year engineering graduate students and motivated senior-level undergraduates, with the goal of providing an introduction to M/NEMS fabrication techniques, selected device applications, and the design tradeoffs in developing systems. The course has no specific prerequisites, other than graduate or senior standing in engineering; otherwise, students will require permission of the instructors.

Learn how to turn a technical idea from a lab, research, or vision into a successful business using the Lean Launchpad process (business model canvas, customer development, running experiments, and agile engineering.) Hands-on experiential class. 15+ hours per week talking to customers, regulators and partners outside the classroom, plus time building minimal viable products. This class is the basis of the National Science Foundation I-Corps with a focus on understanding all the components to build for deep technology and life science applications. Team applications required in March. Proposals may be software, hardware, or service of any kind. See course website http://leanlaunchpad.stanford.edu/. Prerequisite: interest in and passion for exploring whether your technology idea can become a real company. Limited enrollment.

Principled Entrepreneurial Decisions examines how leaders tackle significant inflection points that occur in high-growth entrepreneurial companies. Students learn how to develop principles as a powerful tool to face tough situations that they will encounter in their lives and their chosen career. Cases and guest speakers discuss not only the business rationale for the decisions taken but also how their principles affected those decisions. A capstone project provides frameworks for students to develop their own set of principles. The teaching team brings its wealth of experience in both entrepreneurship and VC investing to the class. Limited enrollment. Admission by application: https://forms.gle/VU36jjGwmsK54CsK9

Course focuses on how to bridge the gap between creation and commercialization with new ideas, inventions, and technology. Comprehensive introduction to patents, copyrights, trademarks, and trade secrets. Covers business strategies and legal aspects of determining what can be owned and licensed, how to determine commercial value, and what agreements and other paperwork is necessary. Discussion includes aspects of Contract and Intellectual Property law as well as provisions of license agreements, NDAs, and their negotiation. All materials provided including many sample documents.

This course is designed to enable graduate students and advanced undergraduate students in science and engineering to hone strategies for career success. Drawing strongly on entrepreneurial principles and lessons from industry, the course complements the traditional curriculum by focusing on career-building tools that students need to improve their professional prospects and achieve their goals. Relevant for those who plan to pursue careers in academia and industry alike, a central focus will be on managing one's career as if it were a start-up, emphasizing principles that empower individuals to take more control of their futures: investing in yourself, building professional networks, taking intelligent risks, and making uncertainty and volatility work to one's advantage. Through a series of in-classroom presentations and interviews - with professors, entrepreneurs, executives, athletes, investors, and thought leaders from diverse fields and sectors - students will gain important knowledge and practical strategies, with course modules on topics such as ideation and innovation, the skill of self-advocacy, the fundamentals of negotiation, building and managing teams, and effective communication and storytelling. Additional modules will focus on biotechnology and deep tech start-up companies, as well as strategies for cultivating a successful academic career. The idea for this course emerged from the instructor's reflections on 30 years of research, teaching, mentorship, and deep entrepreneurial experiences spanning the gamut of approaches to translational science - academic discovery, invention, conceiving of and leading multi-institutional research centers, building research and business teams, launching and financing start-ups, building business models to advance real-world applications of cutting-edge science, and seeing through research-based companies to success (including growing an idea into a multi-billion dollar company). For this course, students will be expected to complete relevant reading assignments, participate actively in class dialogue, and complete regular writing assignments focused on course topics as they relate to ones own career-building needs and professional aspirations. Students may also have opportunities to lead class discussions on topics of interest.

Interdepartmental. Problems in all branches of fluid mechanics, with talks by visitors, faculty, and students. Graduate students may register for 1 unit, without letter grade; a letter grade is given for talks. May be repeated for credit.

Special studies, lab work, or reading under the direction of a faculty member. Often research experience opportunities exist in ongoing research projects. Students make arrangements with individual faculty and enroll in the corresponding section. Prerequisite: consent of instructor.

The course employs a design thinking approach to help fellows develop a point of view about their life and career. The course focuses on an introduction to design thinking, the integration of work and worldview, and practices that support vocation formation. Includes seminar-style discussions, role-playing, short writing assignments, guest speakers, and individual mentoring and coaching. Open to DCI (Distinguished Career Institute) Fellows only. Additional course information at http://www.designingyourlife.org.

Graduate seminar featuring non-technical talks by engineers from academia and industry. The theme for 2024 is "Let's Get Real!" Discussion is encouraged as graduate students share experiences and learn with speakers and each other. Possible topics of discussion range from time management and career choices to diversity, health, and family. Several optional informal dinners are hosted after the seminar to continue conversation with the speakers. Speaker list will be posted at: https://stanfordmewomen.weebly.com/seminar.html. May be repeated for credit.

Wondering how to weave together what really fits you, is doable, and will be satisfying and meaningful? Have more questions than answers? Have too many ideas for your career, or not enough? This course applies the mindsets and innovation principles of design thinking to the "wicked problem" of designing your life and vocation. Students gain awareness and empathy, define areas of life and work on which they want to work, ideate about ways to move forward, try small prototypes, and test their assumptions. The course is highly interactive. It will conclude with creation of 3 versions of the next 5 years and prototype ideas to begin making those futures a reality. The course will include brief readings, writing, reflections, and in-class exercises. Expect to practice ideation and prototyping methodologies, decision making practices and to participate in interactive activities in pairs, trios, and small groups. Seminar open to all graduate students and Postdocs in all 7 schools. Additional course information at http://lifedesignlab.stanford.edu/dtp.

For students interested in an academic career and who anticipate designing science or engineering courses at the undergraduate or graduate level. Goal is to apply research on science and engineering learning to the design of effective course materials. Topics include syllabus design, course content and format decisions, assessment planning and grading, and strategies for teaching improvement.