Tag Archives: K-12

UK Young Engineers Competitions

Engineering Students

Young Engineers is a organization in the United Kingdom that supports engineering events and competitions. Established in 1984, in 2005 there were 1,100 active clubs with over 18,000 club members (36% female).

The site is packed with information on events and especially photos. See the Young Engineer for Britain Galleries and Robotic Games.

Related: Engineering challengeMiddle School Students in Solar Car Competition2006 FIRST Robotics Competition Regional EventsContraption Engineering Fair

What Kids can Learn

This is a fascinating interview discussing what children can learn if given a computer and little, if any, instruction. Very Cool. Links on the progress since this interview are at the end of the post.

Q: This is your concept of minimally invasive education?

A: Yes. It started out as a joke but I’ve kept using the term … This is a system of education where you assume that children know how to put two and two together on their own. So you stand aside and intervene only if you see them going in a direction that might lead into a blind alley.

The interview explores what happened when:

Mitra simply left the computer on, connected to the Internet, and allowed any passerby to play with it. He monitored activity on the PC using a remote computer and a video camera mounted in a nearby tree.

What he discovered was that the most avid users of the machine were ghetto kids aged 6 to 12, most of whom have only the most rudimentary education and little knowledge of English. Yet within days, the kids had taught themselves to draw on the computer and to browse the Net. Some of the other things they learned, Mitra says, astonished him.

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Open Access Education Materials

Watch a video of Richard Baraniuk (Rice University professor speaking at TED) discussing Connexions: an open-access education publishing system. The content available through Connexions includes short content modules such as:

What is Engineering??:

Engineering is the endeavor that creates, maintains, develops, and applies technology for societies’ needs and desires.

One of the first distinctions that must be made is between science and engineering.

Science is the study of what is and engineering is the creation of can be.

and: Protein Folding, as well as full courses, such as: Fundamentals of Electrical Engineering I and Physics for K-12.

Related: Google technical talk webcasts (including a presentation by Richard Baraniuk at Google) – podcasts of Technical Talks at Googlescience podcast postsBerkeley and MIT courses online

Engineering Resources for K-12 Teachers

Teach Engineering, funded by NSF, provides k-12 teachers “teacher-tested, standards-based engineering content” to “enhance learning, excite students and stimulate interest in science and math through the use of hands-on engineering.”

The TeachEngineering digital library provides teacher-tested, standards-based engineering content for K-12 teachers to use in science and math classrooms. Engineering lessons connect real-world experiences with curricular content already taught in K-12 classrooms. Mapped to educational content standards, TeachEngineering’s comprehensive curricula are hands-on, inexpensive, and relevant to children’s daily lives.

Available modules include: Engineering and the Human Body, Exploring Solar Power, Engineering: Simple Machines and Environmental Engineering.

k-12 Engineering Education

Presentation by Ioannis Miaoulis, President and Director of the Museum of Science, Boston on k-12 Engineering Education.

Massachusetts was the first state in the nation to include Engineering as a topic in its Learning Standards.

Public schools from pre-kindergarten to high school are now including engineering as a new discipline. Dr. Miaoulis describes the value of including Engineering in the formal curriculum content for elementary, middle school and high school level. He also discusses the necessary partnerships between the state Department of Education, federal government, school districts, teacher groups, colleges, universities and museums and industry that are supporting this effort and the evolution of the program.

Report on K-12 Science Education in USA

The National Assessment of Educational Progress from the United States Department of Education is the definitive report on k-12 science education based on testing 4th, 8th and 12th grade students. The report provides a huge amount of data on testing results. At first look, it seems basically things stayed the same over the last 5 years.

Various differences are shown (for example: “Most states showed no improvement at grades 4 and 8. Five of the 37 participating states, however, did improve between 2000 and 2005 – and did so at both grades.”). However, I remain a bit skeptical of reading much into such claims. Even if you changed nothing (just retest the students the next month say) and then look for differences between the two sets of data it is possible to find seemingly interesting differences. It is very easy to be fooled when you have a large pool of data and search for any differences that seem interesting.

We commented on one example of why it is important to be careful in making conclusions based on data recently (in our management improvement blog). Most often people look for the differences to highlight the differences. That creates a bias to find such differences, which leads me to be a bit skeptical of such claims without an explanation of why the data is convincing that such a difference is significant and not just variation in the data.

The data from the test does provide a resource for those interested in exploring these matters, which is good.

The Department of Education provides sample questions online. Try them yourself: they are interesting. Unfortunately, for some questions requiring written responses, they don’t actually provide what the answer should be.

Science scores up in grade four, stalled in grades 8 and 12

News stories:

  • Test Shows Drop in Science Achievement for 12th Graders by Sam Dillon
  • Top of the class: Virginia a model for science education
    Forty percent of fourth-grade students and 35 percent of eighth-graders in Virginia’s public schools have a solid grasp of physical and life science, the NAEP reported.

    Nationally, the proficiency percentage for fourth-grade students is 29 percent, and 30 percent for those in eighth grade.

  • State pupils improving in science tests – but 4th- and 8th-graders still not doing as well as their peers across the nation
    In fourth-grade testing, only Mississippi scored below California, while California’s eighth-grade scores ranked 42nd out of 44 states. Of California’s fourth-graders, 17 percent were proficient or better in science, and half scored below the basic level. Among California eighth-graders, 18 percent were proficient or better, while 56 percent were below basic.

    Wide achievement gaps persist for California’s economically disadvantaged students, with 73 percent scoring below the basic level, and among its ethnic minorities, with 74 percent of black eighth-graders and 73 percent of Hispanic eighth-graders scoring below basic.

Science for Kids

‘Sciencing’ with kids by Prakash Rao:

Let us understand well that science is better learnt through activities, experiences, experiments and projects.

Children’s experiences need to be real, concrete and [tangible]. We should never get carried away by just contents and facts. Link experiences to children’s life. Then they will feel a desire to know.

Children are naturally inquisitive. Mainly we need to provide opportunities for them to do what they would do naturally. In previous posts we have highlighted many ways to give kids the chance to learn and figure out how things work.

Science Education in the USA, Japan…

Press release from the US Department of Education: U.S. Science Lessons Focus More on Activities, Less on Content, Study Shows

A video study of 8th-grade science classrooms in the United States and four other countries found U.S. teachers focused on a variety of activities to engage students but not in a consistent way that developed coherent and challenging science content.

In comparison, classrooms in Australia, the Czech Republic, Japan, and the Netherlands exposed 8th graders to science lessons characterized by a core instructional approach that held students to high content standards and expectations for student learning.

The National Center for Education Statistics in the U.S. Department of Education’s Institute of Education Sciences today released these and other findings in a report titled Teaching Science in Five Countries: Results From the TIMSS 1999 Video Study that draws on analysis of 439 randomly selected videotaped classroom lessons in the participating countries.

The results of the newly released science study highlight variations across the countries in how science lessons are organized, how the science content is developed for the students, and how the students participate in actively doing science work.

For example, in Japan, the lessons emphasized identifying patterns in data and making connections among ideas and evidence. Australian lessons developed basic science content ideas through inquiry. Whereas in the Netherlands, independent student learning is given priority. Dutch students often kept track of a long-term set of assignments, checking their work in a class answer book as they proceeded independently.

In the Czech Republic, students were held accountable for mastering challenging and often theoretical science content in front of their peers through class discussions, work at the blackboard, and oral quizzes.

In the United States, lessons kept students busy on a variety of activities such as hands-on work, small group discussions, and other “motivational” activities such as games, role-playing, physical movement, and puzzles. The various activities, however, were not typically connected to the development of science content ideas. More than a quarter of the U.S. lessons were focused almost completely on carrying out the activity as opposed to learning a specific idea.

The science report is the second released by TIMSS 1999 Video Study. The first report, focused on 8th grade mathematics teaching, was released in 2003.

To view the reports and for more information: Trends in International Mathematics and Science Study

via: Study suggests U.S. science teaching falls short on content

Science Education in the 21st Century

Photo of Dr. Carl Wieman

Science Education in the 21st Century: Using the Tools of Science to Teach Science podcast by Dr. Carl Wieman, recipient of the Nobel Prize in Physics in 2001. Also received the first NSF Distinguished teaching Scholars award (NSF’s “highest honor for excellence in both teaching and research”) and the National Professor Of The Year (CASE and Carnegie Foundation).

Dr. Carl Wieman, recipient of the Nobel Prize in Physics in 2001, discusses the failures of traditional educational practices, even as used by “very good” teachers, and the successes of some new practices and technology that characterize this more effective approach. Research on how people learn science is now revealing how many teachers badly misinterpret what students are thinking and learning from traditional science classes and exams.

However, research is also providing insights on how to do much better. The combination of this research with modern information technology is setting the stage for a new more effective approach to science education based on using the tools of science. This can provide a relevant and effective science education to all students.

Podcast recording 21 Nov 2005 at the University of British Columbia.

Text of March 15, 2006 Dr. Wieman testimony to the US House of Representatives Science Committee.

Nobel Laureate Joins UBC to Boost Science Education

via: Maintaining scientific humility

Engineering is Elementary

Elementary Engineers: Engineering concepts should be taught at an early age by Polly Roberts, Richmond.com:

Christine M. Cunningham, vice president of research at the Museum of Science, Boston spoke to more than 200 Virginia elementary school teachers last week at the 10th Annual Children’s Engineering Convention in Glen Allen.

The EiE program then provides teachers with lesson plans, handouts and background information so they can discuss the engineering aspects of the book with their students and have them participate in their own “engineering design challenge,” which in this case would be developing a water purifier.

Cunningham said the program helps build and reinforce skills such as problem solving, data analysis, teamwork, creativity and more. Plus, starting the lesson with a book incorporates literacy.

Engineering is Elementary (EiE): Engineering and Technology Lessons For Children

This is another nice resource for teachers including lesson plans such as: Catching the Wind – Designing Windmills. For more resources see our: Science and Engineering Link Directory