1. IEEE EAB Teacher In-service Program Presentation Atlanta, GA Ralph Painter, Florida West Coast Section Douglas Gorham, IEEE Educational Activities 22 July 2005

2. IEEE (The Institute of Electrical and Electronics Engineers) l IEEE has over 365,000 members in more than 150 countries l IEEE represents 40 engineering societies l Computer, Industrial Electronics, Power, Vehicular Technology, Industry Applications l IEEE is committed to enhancing mathematics, science, and technological literacy K-16 l This commitment is reflected in the IEEE Constitution l IEEE is a non-profit 501 (c) 3 organization

3. Objectives l To promote an awareness of the need for technological literacy l To provide a hands-on demonstration of mathematics, engineering, and technology for classroom use l To promote awareness of the connections between mathematics, science, and technology standards l To provide information about resources available to support mathematics, science, and technology instruction

4. What is Technological Literacy? l Technological literacy is the ability to use, manage, assess and understand technology. (STL, 2000, p. 242) l Change is a ubiquitous feature of contemporary life, so learning with understanding is essential to enable students to use what they learn to solve the new kinds of problems they will inevitably face in the future. (PS, 2000, p. 20-21) Students’ work with scientific investigations can be complemented by activities in which the purpose is to meet a human need, solve a human problem, or develop a product…(NSES, 1996, pg. 161)

5. Key Ideas l Technology is the modification of the natural world in order to satisfy perceived human needs and wants (ITEA, STL, p. 242). l Technology is essential in teaching and learning mathematics; it influences the mathematics that is taught and enhances students’ learning (PS, p. 11). l Any presentation of science without developing an understanding of technology would portray an inaccurate picture of science (National Research Council, National Science Education Standards, p. 190).

6. “Technically Speaking” Report “As a society, we are not even fully aware of or conversant with the technologies we use every day. In short, we are not ‘technologically literate.’ “ Source: NAE. (2002). Technically Speaking: Why All Americans Need to Know More About Technology. p. 1. Washington, DC: National Academy Press.

7. Percentage of Science Degrees Awarded Science degrees include life sciences, physical sciences, mathematics, statistics, computer sciences, engineering, manufacturing, and building Source: Organization of Economic Cooperation and Development

8. Build Your Own Robot Arm Atlanta, GA Ralph Painter, Florida West Coast Section Douglas Gorham, IEEE Educational Activities 22 July 2005

9. Principles & Standards for School Mathematics l Geometry: l Use visualization, spatial reasoning, and geometric modeling to solve problems l Analyze characteristics and properties of two- and three- dimensional geometric shapes and develop mathematical arguments about geometric relationships l Problem Solving: l Recognize and apply geometric ideas in areas outside of the mathematics classroom l Apply and adapt a variety of appropriate strategies l Communication: l Communicate mathematical thinking coherently and clearly to peers, teachers, and others

10. National Science Education Standards Standard E: Science and Technology l Abilities to distinguish between natural objects and objects made by humans l Abilities of technological design l Understandings about science and technology l Communicate the process of technological design l Interactions of energy and matter l Motion and force

11. Standards for Technological Literacy Students will develop an understanding of… l Standard 7. the influence of technology on history. l Standard 8. the attributes of design. l Standard 9. engineering design. l Standard 10. the role of troubleshooting, research and development, invention and innovation, and experimentation in problem solving. Students will develop … l Standard 11. the abilities to apply the design process. l Standard 19. an understanding of and be able to select and use manufacturing technologies.

12. Outline and Procedures l Divide into teams of 3 l Brainstorm and create a sketch of your design l Build a model of your design with given materials l Test your model l Discuss and agree upon a redesign, if needed l Rebuild your robot arm l Retest your model l Answer reflection questions as a team

13. Reflection l What was one thing you liked about your design? l Are there algebraic principles that can be applied to this activity? l What is one thing you would change about your design based on your experience? l How might you incorporate this activity into your classroom instruction?

14. Rotational Equilibrium: A Question of Balance Atlanta, GA Ralph Painter, Florida West Coast Section Douglas Gorham, IEEE Educational Activities 22 July 2005

15. Principles & Standards for School Mathematics l Data Analysis and Probability: l Formulate questions that can be addressed with data and collect, organize and display relevant data to answer them l Develop and evaluate inferences and predictions based on data l Algebra: l Understand patterns, relations, and functions; l Represent and analyze mathematical situations and structures using algebraic symbols; l Use mathematical models to represent and understand quantitative relationships; l Analyze change in various contexts.

16. National Science Education Standards Standard A: Science as Inquiry: l Abilities necessary to do scientific inquiry l Understandings about scientific inquiry Standard B: Physical Science: l Understanding of motions and forces l Interactions of energy and matter Standard E: Science and Technology l Abilities of technological design l Understandings about science and technology l Communicate the process of technological design Standard K-12: Unifying Concepts and Processes l Evidence, models, and explanations

17. Standards for Technological Literacy Students will develop an understanding of… l Standard 8. the attributes of design. l Standard 10. the role of troubleshooting, research and development, invention and innovation, and experimentation in problem solving. Students will develop… l Standard 11. the abilities to apply the design process.

20. Rotational Equilibrium- Step One l Prepare the materials

21. Rotational Equilibrium- Step Two l Team predictions

22. Rotational Equilibrium- Step Two

23. Eq. (e) 3 W X 3 = W Y 3, therefore Y 3 = 3X 3 Eq. (f) X 3 + Y 3 = 300mm

24. Rotational Equilibrium- Step Two Eq. (e) is rearranged: Y 3 = 3X 3 Eq. (f): is rearranged: Y 3 = - X 3 + 300mm.

25. Rotational Equilibrium- Step Two Generate points for: Y 3 = 3X 3 X 3 0 50 100 Y 3 Eq. (f): is rearranged: Y 3 = - X 3 + 300mm. X 3 0 100 200 Y 3

26. Rotational Equilibrium- Step Two Generate points for: Y 3 = 3X 3 X 3 0 50 100 Y 3 0 150 300 Eq. (f): is rearranged: Y 3 = - X 3 + 300mm. X 3 0 100 200 Y 3 0 200 100

27. Rotational Equilibrium- Step Two

28. Rotational Equilibrium- Step Three l Build your mobile

29. Rotational Equilibrium- Step Four l Record your actual results

30. Rotational Equilibrium- Step Five l Analyze your results

31. Reflection l What was one thing you liked about your design? l Are there algebraic principles that can be applied to this activity? l Are there geometric principles used in this activity? l What is one thing you would change about your design based on your experience? l How might you incorporate this activity into your classroom instruction?

32. ZOOM INTO ENGINEERING l Students explore and experiment with basic engineering principles through fun, hands-on activities l A focus on problem solving and inquiry- based learning l Grades K-5 l Aligned with education standards l Activity guide available l www.asce.org/kids

33. BUILDING BIG l A focus on problem solving and inquiry-based learning l Grades 6-8 l Aligned with education standards l Includes a ‘Hands On Glossary’ of engineering terms l Activity guide available l www.asce.org/kids

34. IDEAS l Alternative Energy - Wind Powered Machines l Amusement Park And Playground Physics l Buoyant Vehicles l Geodesic Domes And Sheltering Structures l Historical Catapults l Investigating Isaac’s Ideas l Slow Roller And Friction Experiments Low-Cost, “Hands-On” Engineering Projects For Middle School Math, Science And Technology www.asme.org/education/precollege/

35. l Engineers: Who They Are And What They Do l The Wonderful World Of Gears l Why Do Planes Fly? l Amusement Park Roller Coaster l How Tall Is That Flagpole Anyway? l Waste Not, Want Not - How To Get Rid Of Your Garbage l Ethics For Students ENGINEERS SOLVE PROBLEMS Includes Lesson Rationale, Objectives, Lesson Plan And Enrichment Activities

36. TEACHER IN-SERVICE PROGRAM l Engineers Develop and Present Technologically Oriented Topics To Pre- College Educators l Includes Practical, Applicable, Hands- On Activities l Promotes Mathematics, Science and Technological Literacy l 15 Lesson plans available in English and Spanish at: www.ieee.org/organizations/eab/precollege/tispt

37. IEEE VIRTUAL MUSEUM l IEEE History Center Outreach Project for Educators, Parents and Students Age 10-18 l Examines History of Technology l Demonstrates How Various Technologies Work l Increases Understanding of the Impact of Engineering and Technology on Society

38. DOCUMENT RESOURCES l Standards for Technological Literacy: Content for the Study of Technology, 2000. ITEA l Pearson, G., and A. T. Young, eds. 2002. Technically Speaking: Why All Americans Need to Know More About Technology. Committee on Technological Literacy. Washington, D.C.: National Academy Press l Technological Literacy Counts: Workshop Proceedings, 1998. IEEE l The Design for Science Literacy, 1999. AAAS

39. DOCUMENT RESOURCES CONT’D l ITEA. (2004, September). ITEA/Gallup Poll Reveals What People Think About Technology. Reston, Va.: ITEA l National Research Council. (1996). National Science Education Standards. Washington, D.C.: National Academy Press l National Council of Teachers of Mathematics. (2000). Principles and Standards for School Mathematics. Author

40. WEBSITE RESOURCES l IEEE- www.ieee.org/organizations/eab/precollege l ACS- www.acs.org/edresources.htmwww.acs.org/edresources.htm l ASCE- www.asce.org/kids l Virginia Tech- www.teched.vt.edu/ctte l Texas- www.texastechnology.com l NASA- l http://aesp.nasa.okstate.edu/florida l NCTM- www.nctm.org l ITEA- www.iteawww.org

41. WEBSITE RESOURCES CONT’D l ASME- www.asme.org/education/precollege/ l NAE- www.nae.edu/techlit l Project Lead The Way- www.pltw.org l APS- www.aps.org l NSTA- www.nsta.org l SAE- www.awim.sae.org l Eisenhower National Clearinghouse- www.enc.org l www.gettech.org l www.library.advanced.org/11686/

42. Contact Information IEEE Ralph Painter rdpainter@tecoenergy.com Douglas Gorham d.g.gorham@ieee.org ASCE Jane Howell jhowell@asce.org ASME Marina Stenos stenosm@asme.org