This week I led a four-hour training session - "Project Based Learning in the STEM Classroom." Here's a link to the Google site I used to support my workshop. You'll find links to a variety of resources to help teachers get started using a PBL approach in their classrooms - handouts, videos, project ideas - plus tips on how to plan, manage, and evaluate PBL. I included some Google forms as collaboration tools. They didn't get much action, but they had potential for collaboration. (I reset them to no longer accept new data.)
For more on the workshop approach see my post "Solve This Problem, You'll Learn the Skills Along the Way"
I'm in the Wisconsin Dells today to deliver a four-hour training session for CESA 6. It's entitled "21st Century Skills in Action: Project Based Learning in the STEM Classroom." We'll be using a Turning Point ARS and lots of activities so that participants experience the why, what, and how of PBL in the STEM curriculum.
Students explore their world with an expectation of choice and control that redefines traditional notions of learning and literacy. Educators are discovering that they can motivate students with a PBL approach that engages their students with the opportunity to behave like STEM professionals while solving real-world problems.
I was pleased to read an interesting piece in the NY Times on yesterday's flight. "Computer Studies Made Cool, on Film and Now on Campus" (6/11/11). While the focus is on the growing popularity of computer science, it make a strong case for the project based approach to learning.
The new curriculums emphasize the breadth of careers that use computer science, as diverse as finance and linguistics, and the practical results of engineering, like iPhone apps, Pixar films and robots, a world away from the more theory-oriented curriculums of the past.
The old-fashioned way of computer science is, ‘We’re going to teach you a bunch of stuff that is fundamental and will be long-lasting but we won’t tell you how it’s applied,’ ” said Michael Zyda, director of the University of Southern California’s GamePipe Laboratory, a new games program in the computer science major. With the rejuvenated classes, freshman enrollment in computer science at the university grew to 120 last year, from 25 in 2006. ...
To hook students, Yale computer science professors are offering freshman seminars with no prerequisites, like one on computer graphics, in which students learn the technical underpinnings of a Pixar movie.
“Historically this department has been very theory-oriented, but in the last few years, we’re broadening the curriculum,” said Julie Dorsey, a professor.
She also started a new major, computing and the arts, which combines computer science with art, theater or music to teach students how to scan and restore paintings or design theater sets.
Professors stress that concentrating on the practical applications of computer science does not mean teaching vocational skills like programming languages, which change rapidly. Instead, it means guiding students to tackle real-world problems and learn skills and theorems along the way.
“Once people are kind of subversively exposed to it, it’s not someone telling you, ‘You should program because you can be an engineer and do this in the future,’ ” said Ms. Fong, the Yale student. “It’s, ‘Solve this problem, build this thing and make this robot go from Point A to Point B,’ and you gain the skill set associated with it.” With other students, she has already founded a Web start-up, the Closer Grocer, which delivers groceries to dorms.
As I blogged in my Apollo 13 video post, Watch Problem Based Learning in Action "While our students have been conditioned to 'learn the basics - then solve the problem,' that's not how life always works."
Here's a great 4-minute video by Dan Meyer that gives three examples of how to bring real-life problem scenarios into the math classroom. To paraphrase Dan, "In these examples student have to first ask the question - what information do I need to solve this problem? The textbook usually gives you that information. But here students build the problem and decide what matters. The question that's usually buried at the bottom - it's the last thing in the textbook problem - now becomes the first thing in the student's mind. I want to make that question "irresistible" to the student, so they have to know the answer." For more great ideas on how "math makes sense of the world" - go to Dan's blog dy/dan
As you watch this video, think about what could happen in schools if adults got out of the way.
You'll hear students say things like, "A subject comes up that I don't know about, and instead of glossing over it, I truly find myself thinking was is that about? I could learn about it! I'm finding questions in everything." And "We learned how to learn, we learned how to teach, we learned how to work."
Of course, it's easy to discount these kids as atypical. Marginalizing them is far easier than wondering why other high school students are stuck doing worksheets.
For more information on the project and associated lesson plans for students see: "Independence Day: Developing Self-Directed Learning Projects"
The latest results from the Program for International Student Assessment (PISA) are public, and already some pundits are declaring it "a Sputnik wake-up." Others shout back that international comparisons aren't valid. Rather than wade into that debate, I'd rather look more closely at the questions in the PISA test and what student responses tell us about American education. You can put international comparisons aside for that analysis.
Are American students able to analyze, reason and communicate their ideas effectively? Do they have the capacity to continue learning throughout life? Have schools been forced to sacrifice creative problem solving for “adequate yearly progress” on state tests? For more on that last question see my post "As NCLB Narrows the Curriculum, Creativity Declines."
The Program for International Student Assessment (PISA) provides some answers to those questions and offers an insight into the type of problem solving that rarely turns up American state testing. FYI: PISA is an assessment (begun in 2000) that focuses on 15-year-olds' capabilities in reading literacy, mathematics literacy, and science literacy. PISA assesses how well prepared students are for life beyond the classroom by focusing on the application of knowledge and skills to problems with a real-life context. For more examples of PISA questions and data click her.
Do American students learn how to sequence or simply memorize sequences
Here's one insight into what American students can (and cannot do) that can be gleaned from the 2003 PISA test results. We spend a lot of time in school getting students to learn sequential information - timelines, progressions, life cycle of a moth, steps for how to. Typically the teacher teaches the student the sequence and the student correctly identifies the sequence for teacher on the test. Thus we treat a sequence as a ordered collection of facts to be learned, not as a thinking process for students to use. This memorization reduces the student's "mastery" of the chronology to lower order thinking. I was guilty of this when I first started teaching history "Can someone give me two causes and three results of WWII?"
Sample sequencing problem from PISA
The Hobson High School library has a simple system for lending books: for staff members the loan period is 28 days, and for students the loan period is 7 days. The following is a decision tree diagram showing this simple system:
The Greenwood High School has a similar, but more complex library lending system:
All publications classified as “Reserved” have a loan period of 2 days.
For books (not including magazines) that are not on the reserved list, the loan period is 28 days for staff, and 14 days for students. For magazines that are not on the reserved list, the loan period is 7 days for everyone.
Persons with any overdue items are not allowed to borrow anything.
Task
Develop a decision tree diagram for the Greenwood High School Library system so that an automated checking system can be designed to deal with book and magazine loans at the library. Your checking system should be as efficient as possible (i.e. it should have the least number of checking steps). Note that each checking step should have only two outcomes and the outcomes should be labeled appropriately (e.g. “Yes” and “No”).
Student Results
Only 13.5% of US students were able correctly answered the question. Does it really matter if students in Shanghai did any better? (The student results were rated on a rubric scale.)
When students are asked to observe a process and develop a sequence they have an opportunity to use a full spectrum of higher-order thinking skills - they must recognize patterns (analyze), determine causality (evaluate) and then decide how they would communicate what they've learned to others (create). Sequencing can be taught across the curriculum at a variety of grade levels - we simply have to ask the students to observe and do the thinking.
In case you're wondering, correct response should look like this.
Click image to enlarge.
American education has been hijacked by policy makers who don't trust teachers, unions that are over-protective of job security, a private sector eager to privatize, and a standardized testing regime that rewards test prep over genuine learning. In the middle of it all, bored students disconnect from school as they realize that their main function is to be trivialized into a source of data for adults looking for someone to blame.
While America educational leadership offers hollow sound bites about life-long learning, Scotland's Curriculum for Excellence offers us insight into what American kids are missing. This video produced by the Scottish program offer a quick introduction to three project-based approaches. Here's two quotes from the video that say it all:
~ A student, "When you're just copying a text book ... you're looking at results which people have already achieved and proved their work... but when you doing it yourself you get an idea of how things work ... and what you actually need to make things successful."
~ A teacher, "In this approach ... your not teaching the subject in isolation - your teaching in a much more natural way ... with greater depth and more enrichment... there's an accessible point for every child in the class and they can build on that and take it in directions of their own personal interests."
In the coming weeks, schools across the country will reopen. I feel badly for the many teachers and students who will return to the grueling routine of test-prep. Perhaps they have convinced themselves that the foundation of teaching is to tell students something they did not previously know. As Donald Finkel has described it - teaching as telling. Do they see students as computers waiting for instructions? Teachers of high performing students forced to "install" the SAT / AP files while teachers of low performing students "upload" minimum competency on state exams. Different students and goals, but equal in the outcome that nobody will be having much fun.
Last week I attended Project Foundry's "2nd Annual unConference" in Milwaukee and was reminded that there is a growing core of schools and teachers who have rejected the mind-numbing routine of test-prep. I was uplifted knowing that these teachers and their students were getting ready for the rewards of a school year of project-based learning.
Project Foundry is a leading provider of online learning management systems with a focus on the needs of PBL classroom. Their conference assembled 60+ educators from across the country. These PBL teachers share a belief that students can't be programmed for the tests. Instead, they strive to provide a supportive learning environment that will foster the skills, motivation and responsibility for the students to become genuine life-long learners. (Not just the empty promise of typical district mission statement.)
The PBL teachers came from a wide variety of schools (urban / rural, experiential / career, charter / public school, high / low-needs students). They embodied many approaches, but they all shared the goal of helping students take increasing responsibility for their learning. It was no surprise that my keynote talk - "Supporting Reflective Learners" was warmly received by the attendees. See my post for more on my Taxonomy of Reflection.
As I walked into the unConference's host school - the Milwaukee's Professional Leadership Institute, I couldn't help but notice the powerful display of student work on the wall. (At left). It embodied a reflective, project-based approach in action and reminded me that across the country a small, but increasing number of students would embrace a new school year laced with the promise of self-discovery and personal growth.
Note: "In My Shoes", was a school studio project in the arts enrichment program offered by Artists Working in Education (AWE) and proposed and hosted by Milwaukee's Professional Leadership Institute. For a full description of the project see the excellent blog post by unConference attendee, Angie Tenebrini.
Recently I spoke at a project-based learning conference in Wisconsin. I had been reading Michael Pollan's "The Omnivore's Dilemma,” so I had farming on my mind as I drove from the Milwaukee airport to Janesville WI past vast cornfields punctuated by enormous grain silos.
Pollan observes that high-yield corn is a product of genetically identical plants that can be densely planted without fear of any stalks monopolizing resources. As corn dominated the midwestern landscape, the region became an agricultural monoculture of expansive corporate cornfields – pushing out other crops and more diverse family farms. Cheap corn created the "Concentrated Animal Feeding Operation," where never-ending truckloads of feed are used to fatten cattle in the least time possible. "Big" corn and cattle production are artificially supported by vast, but unsustainable, industrial inputs of fossil fuels, petro-chemicals, and an elaborate transportation system.
And somewhere on the drive to Janesville, I got thinking that Pollan's indictment of corporate agriculture might be extended to some aspects of education. The testing regime is turning our kids into a high-yield, uniform commodity. Rows and rows of competent, standardized students, that can be delivered according to employers' specifications for a "skilled workforce.” Children “force fed” in test prep programs in efforts to quickly “fatten” the scores to meet AYP. Like the cornfields and feedlots that are disconnected from local ecosystems, the movement toward national educational standards erodes at local control and innovation.
Fortunately when I got to the conference I saw another side of contemporary education - innovative teachers. It was like walking into a sustainable farmers' market.
The conference was held at the TAGOS Leadership Academy and hosted by Project-Based Learning Systems, the developer of Project Foundry, a web-based management tool for innovative learning environments. Teachers had come from across the country - Chula Vista CA to Waterville ME. Like sustainable farms, their schools were deeply rooted in their communities, each closely tied to its unique local social ecology. Their programs fostered interdisciplinary learning, like the symbiotic polyculture of a farm based on a rotational interplay of crops and animals.
The PBL approach is based on the notion that rather than simply apply bodies of knowledge to problems, the exploration of problems can generate new bodies of knowledge. Teachers didn't attend the conference to simply “sit and get,” they were there to share. After my introductory talk and a planning session using my audience response system, the teachers self-organized into a series of peer-teaching sessions that took them through most the rest of the conference.
The next day I headed home feeling upbeat. I had met many fine teachers and instructional leaders who reminded me of why I went into education. Most of all, I thought about the scores of teachers across the country, working in innovative schools (or perhaps subversively innovating in traditional schools), committed to raising a “crop” that can sustain itself through a life time of learning.
At M.I.T., two introductory courses are still required — classical mechanics and electromagnetism — but today they meet in high-tech classrooms, where about 80 students sit at 13 round tables equipped with networked computers.
Instead of blackboards, the walls are covered with white boards and huge display screens. Circulating with a team of teaching assistants, the professor makes brief presentations of general principles and engages the students as they work out related concepts in small groups.
Teachers and students conduct experiments together. The room buzzes. Conferring with tablemates, calling out questions and jumping up to write formulas on the white boards are all encouraged.
“There was a long tradition that what it meant to teach was to give a really well-prepared lecture,” said Peter Dourmashkin, a senior lecturer in physics at M.I.T. and a strong proponent of the new method. “It was the students’ job to figure it out.”
The problem, say Dr. Dourmashkin and others in the department, is that a lot of students had trouble doing that. The failure rate for those lecture courses, even those taught by the most mesmerizing teachers, was typically 10 percent to 12 percent. Now, it has dropped to 4 percent.
... The traditional 50-minute lecture was geared more toward physics majors, said Eric Mazur, a physicist at Harvard who is a pioneer of the new approach, and whose work has influenced the change at M.I.T.
“The people who wanted to understand,” Professor Mazur said, “had the discipline, the urge, to sit down afterwards and say, ‘Let me figure this out.’ ” But for the majority, he said, a different approach is needed.
“Just as you can’t become a marathon runner by watching marathons on TV,” Professor Mazur said, “likewise for science, you have to go through the thought processes of doing science and not just watch your instructor do it.”
Another shot at progressive education. "The Latest Doomed Pedagogical Fad: 21st-Century Skill" By Jay Mathews Washington Post January 5, 2009. He writes:
Granted, the 21st-century skills idea has important business and political advocates... It calls for students to learn to think and work creatively and collaboratively. There is nothing wrong with that. Young Plato and his classmates did the same thing in ancient Greece. But I see little guidance for classroom teachers in 21st-century skills materials. How are millions of students still struggling to acquire 19th-century skills in reading, writing and math supposed to learn this stuff?
Actually millions of students are learning to think and work creatively, it's just not in school. They do that stuff at home on their own time. Meanwhile much of their class time is now mandated on mind-numbing test prep on those "19th-century skills." Teachers who want to have a more engaging classroom have to sneak it into the curriculum - project-based learning has been pushed to the back of the class.
Columnist's like Mr. Matthews have to realize that new technologies have already put students in charge of the information they access, store, analyze and share. Students are using new digital media to share their creativity with the world.
What can schools do to support learning in the digital age? Monitor the information flow and and thinking in the classroom. This changes the role of teacher from dispensing information to instructional designer. Students can't simply give information back to their teacher. They need a chance to to create a product that asks them to communicate their thinking to a more authentic audience. Teachers will need the support and training to create supportive learning environments that considers basic questions like:
How is information flowing through my class?
What level of thinking skills are students being asked to use?
How do students get to share what they’ve learned? - Who is their audience? - What is their purpose?
Creating is Bloom's highest level of thinking. Creating is not limited to "the creative." We all create when we make new combinations of existing elements. Someone put wheels on the bottom of a scaled-down surfboard and created the skateboard. And so it goes...
While teachers and students are constrained by mind-numbing test prep, the rest of society is working overtime to foster creative connections. In September the annual "IdeaFestival" was held in Louisville, KY. It brings together creative thinkers from different disciplines to connect ideas in science, the arts, design, business, film, technology and education. The festival motto - "If it can possibly go together, it comes together here." Why not apply that perspective in our schools?
Here are some suggestions from the festival on how to come up with new ideas. Many can be easily adapted to help our students discover their creative potential in the classroom.
For more on teaching innovation.
There's an emerging genre of internet videos that fall into the category of "how to's." Lots of folks are offering up instructional guides for how to do everything imaginable from How to Chill a Coke in 2 Minutes to How to Fold a Towel.
Explaining "how to" requires students to research a subject, evaluate what's important, and create a guide for someone else to follow. It gives them an opportunity to write for an authentic audience and purpose and use skills that rank very high on Bloom's taxonomy.
If you want to get your students writing and shooting these videos here's some suggestions:
1. Get the new Flip Ultra video camera - remarkably easy to use and only $114 at Amazon. Works with Mac or PC. I've been using one for a few months and I'm impressed with the sound and image quality and the simplicity of use.
2. Have students take a look at this ingenious "how to" done by Common Craft - no elaborate props or on-screen talent required. The Flip camera won't be able to shoot as closely as the Common Craft video below, but students can easily recreate the look on a larger scale using the classroom white board and the optional Flip Ultra tripod ($14 at Amazon).
3. Post the video to TeacherTube - a safe alternative to YouTube.
OK - time to make a movie!
Note on editing. The Flip video comes with its own software that works with Mac or PC. Ingeniously, the software resides on the camera and works anytime you plug the Flip USB into a computer.� The Flip video files are created in an AVI format that can be edited on a PC using software like MovieMaker. Mac iMovie won't accept the Flip video AVI format directly, but you can convert an AVI file to a (iMovie-friendly) m4v file format using free iSquint software. Students can design, shoot and edit the video, then do a voice over. That way they can focus on the visual message separately from the audio message.
8/08 Update: The latest version of Flip video software will allow direct import of files into Mac iMovie!