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 Through it's research, the Designing Education Lab has developed a variety of classroom learning tools. As part of our mission, we want to make these materials publicly available. Here are some of the materials we have developed:  
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Through research, the Designing Education Lab has developed a variety of classroom learning tools. As part of our mission, we want to make these materials publicly available. Here are some of the materials we have developed:<br>
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*Stanford's Introductory Statics Course (E14) has gone under several changes in the past couple of years based on the work of the DEL team. Here are some materials discribing and using the new method: [http://dl.dropbox.com/u/28709293/Designing%20Education%20Lab/Curricular%20Tools/E14%20Worksheets.pdf Worksheets without Answers] [http://dl.dropbox.com/u/28709293/Designing%20Education%20Lab/Curricular%20Tools/E14%20Workshets_ALL_withAnswers.pdf Worksheets with Answers]  
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*Educating Young Stem Thinkers: The course, which will span two quarters, introduces Stanford students to the design&nbsp;thinking process, the national conversations about the future of STEM careers, and&nbsp;provides opportunities to work with middle school students and K-­12 teachers in&nbsp;STEM-­based after-­school activities and intercession camps. The course will be both&nbsp;theory and practice-­focused:  
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*D.Loft STEM ITEST: The purpose of this project is to introduce students to STEM&nbsp;engineering careers by leveraging the power of a design thinking approach to learning in school&nbsp;intersession camps. The project centers on the critical need&nbsp;to foster an interest in STEM careers, as it imperative for the United States to compete globally.&nbsp;A focus on innovation, creativity, critical thinking, problem solving,&nbsp;communication and collaboration is essential to prepare our students for the challenges of learning in the&nbsp;21st century:
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[[Image:E14BikeLab.JPG|frame|left|E14BikeLab.JPG]]
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*'''Solid Mechanics Concept Worksheets:'''&nbsp;This instrument is used in the class Introduction to Solid Mechanics (ENGR-14) as a student self-assesd measure of conceptual learning.&nbsp;[http://dl.dropbox.com/u/28709293/Designing%20Education%20Lab/Curricular%20Tools/E14%20Worksheets.pdf Worksheets without Answers] [http://dl.dropbox.com/u/28709293/Designing%20Education%20Lab/Curricular%20Tools/E14%20Workshets_ALL_withAnswers.pdf Worksheets with Answers]
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*'''[[Madison Longboard]]: '''This case study, lab worksheet and lecture visuals are used in&nbsp;Introduction to Solid Mechanics (ENGR-14) to introduce students to entreprenerial concepts within the context of core mechnaical engineering course work. [[Madison Longboard|Click on this link]] for more details and materials.
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*'''Vector Calculus'''&nbsp;'''Modules: '''This tool is used in the class Introduction to Solid Mechanics (ENGR-14) by both faculty and students to assess vector calculus skills in the first weeks of the class to help identify those students who may need "math booster" assistance. &nbsp;[https://sites.google.com/a/stanford.edu/vector-math-review/ Vector Calculus Module]
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[[Image:E14BridgeLab.jpg|frame|right|E14BridgeLab.jpg]]<br>
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*'''Educating Young Stem Thinkers:''' The course, which will span two quarters, introduces Stanford students to the design&nbsp;thinking process, the national conversations about the future of STEM careers, and&nbsp;provides opportunities to work with middle school students and K-­12 teachers in&nbsp;STEM-­based after-­school activities and intercession camps. The course will be both&nbsp;theory and practice-­focused:&nbsp;[http://dl.dropbox.com/u/28709293/Designing%20Education%20Lab/Curricular%20Tools/Syllabus-Educating%20Young%20STEM%20Thinkers-1.pdf Syllabus]<br>
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*'''Research Informed Practices for Inclusive STEM Classrooms: Strategies to Close the Gender Gap''': This literature review aims to bridge research to practice by identifying strategies for educators as they work to capture students’ interest in STEM and retain students who are already interested. Seven “key practices” for creating gender-inclusive STEM classrooms were identified through a comprehensive literature review of social science research in gender and education. After presenting the research for each practice, implementation strategies and directions for future research are suggested. [[Media:ASEE 2013 Scutt.pdf|Paper]] <br>
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*'''D.Loft STEM ITEST:''' The purpose of this project is to introduce students to STEM&nbsp;engineering careers by leveraging the power of a design thinking approach to learning in school&nbsp;intersession camps. The project centers on the critical need&nbsp;to foster an interest in STEM careers, as it imperative for the United States to compete globally.&nbsp;A focus on innovation, creativity, critical thinking, problem solving,&nbsp;communication and collaboration is essential to prepare our students for the challenges of learning in the&nbsp;21st century:&nbsp;[http://dl.dropbox.com/u/28709293/Designing%20Education%20Lab/Curricular%20Tools/iTEST%20Statement%20of%20Work%202-11-10%20Final.pdf iTest Statement of Work]
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[[Image:Mechdiss.jpg|frame|left|Mechdiss.jpg]]
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*'''Mechanical Dissection:''' An approach to teaching students about engineering concepts and design principles by having them explore the engineered products around them. This exploration involves having students work in small teams to disassemble and reassemble machines. This exploration leads to insight on materials, function, design alternatives, human factors and manufacturing. [http://www-adl.stanford.edu/ Syllabus]

Latest revision as of 15:53, 1 July 2013

Through research, the Designing Education Lab has developed a variety of classroom learning tools. As part of our mission, we want to make these materials publicly available. Here are some of the materials we have developed:


E14BikeLab.JPG


  • Madison Longboard: This case study, lab worksheet and lecture visuals are used in Introduction to Solid Mechanics (ENGR-14) to introduce students to entreprenerial concepts within the context of core mechnaical engineering course work. Click on this link for more details and materials.



  • Vector Calculus Modules: This tool is used in the class Introduction to Solid Mechanics (ENGR-14) by both faculty and students to assess vector calculus skills in the first weeks of the class to help identify those students who may need "math booster" assistance.  Vector Calculus Module
E14BridgeLab.jpg

  • Educating Young Stem Thinkers: The course, which will span two quarters, introduces Stanford students to the design thinking process, the national conversations about the future of STEM careers, and provides opportunities to work with middle school students and K-­12 teachers in STEM-­based after-­school activities and intercession camps. The course will be both theory and practice-­focused: Syllabus


  • Research Informed Practices for Inclusive STEM Classrooms: Strategies to Close the Gender Gap: This literature review aims to bridge research to practice by identifying strategies for educators as they work to capture students’ interest in STEM and retain students who are already interested. Seven “key practices” for creating gender-inclusive STEM classrooms were identified through a comprehensive literature review of social science research in gender and education. After presenting the research for each practice, implementation strategies and directions for future research are suggested. Paper


  • D.Loft STEM ITEST: The purpose of this project is to introduce students to STEM engineering careers by leveraging the power of a design thinking approach to learning in school intersession camps. The project centers on the critical need to foster an interest in STEM careers, as it imperative for the United States to compete globally. A focus on innovation, creativity, critical thinking, problem solving, communication and collaboration is essential to prepare our students for the challenges of learning in the 21st century: iTest Statement of Work


Mechdiss.jpg
  • Mechanical Dissection: An approach to teaching students about engineering concepts and design principles by having them explore the engineered products around them. This exploration involves having students work in small teams to disassemble and reassemble machines. This exploration leads to insight on materials, function, design alternatives, human factors and manufacturing. Syllabus
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