Childhood Music Lessons ‘Leave Lasting Brain Boost’

“According to the study featured in this article on the NZ Stuff website, a child learning a musical instrument will retain brain benefits that last long into his or her adult life.”

via Stuff.co.nz

Learning a musical instrument as a child gives the brain a boost that lasts long into adult life, say scientists.

Adults who used to play an instrument, even if they have not done so in decades, have a faster brain response to speech sounds, research suggests.

The more years of practice during childhood, the faster the brain response was, the small study found.

The Journal of Neuroscience work looked at 44 people in their 50s, 60s and 70s.

The volunteers in the study listened to a synthesised speech syllable, “da”, while researchers measured electrical activity in the region of the brain that processes sound information – the auditory brainstem.

Despite none of the study participants having played an instrument in nearly 40 years, those who completed between four and 14 years of music training early in life had a faster response to the speech sound than those who had never been taught music.

The study took place at the Auditory Neuroscience Laboratory at Northwestern University in Illinois, US.

Lifelong skill

As people grow older, they often experience changes in the brain that compromise hearing. For instance, the brains of older adults show a slower response to fast-changing sounds, which is important for interpreting speech.

It could be that learning an instrument in childhood causes a fixed change in the brain that is retained throughout life.

Or, music classes somehow prepare the brain for future auditory learning, say the researchers.

Past work by the same team found younger adults were better listeners if they had been taught an instrument as a child.

Experts also believe musical training – with an emphasis on rhythmic skills – can exercise the auditory-system.

But these studies are all relatively small and cannot ascertain if it is definitely musical training that is causing the effect.

Arguably, children offered the opportunity to learn an instrument, which can be expensive, may come from more privileged backgrounds and this may have an influence.

Commenting on the study, Michael Kilgard from the University of Texas, who was not involved with the research, said: “Being a millisecond faster may not seem like much, but the brain is very sensitive to timing and a millisecond compounded over millions of neurons can make a real difference in the lives of older adults.”

The Digital Lives of Teens: The Key Word is Trust

Matt Levinson from Edutopia talks about engendering trust in monitoring the digital lives of our teens. From the article: ‘School communities need to create partnerships with parents through developing shared language, social media agreements, intervention steps, proactive curricular development and media literacy.’ Read on for more . . .”

via Edutopia

Are We Preparing Graduates for the Past or the Future?

“Are we preparing students for the past or the future? A truly powerful question that forces everyone involved in education (and the business sector, for that matter) to rethink the essential skills needed for success outside of the classroom in a job market where most students are preparing for a job that probably does not exist yet. The answer to the question is ‘no’! Despite the valiant efforts of teachers and administrators, the students are not prepared for a volatile, uncertain, complex, and ambiguous future. Carol Carter at the Huffington Post shares her views on education and its need for change. She also shares wonderful resources to further study the needs of students now and in the future. ”

via Huffington Post

Two weeks ago, I spoke at the International Habits of Mind Conference in Malaysia alongside college and K-12 faculty from Southeast Asia and countries like Iran, New Zealand, and Australia. Outside of the conference, a question came up among some of the speakers:

Are we preparing students for the past or the future?

This question leads to even more questions: If education paradigms don’t shift to meet tomorrow’s needs, will high school and college graduates have the skills to find or create employment opportunities? Do schools and faculty have a responsibility to realize and adapt their lessons to our new economy’s needs and demands? If students aren’t in a learning environment where their gifts and talents can flourish, will they be able to participate in the rapidly changing global economy?

To understand how the working world has changed over the last few decades, let’s look at a typical work culture of the past:

• Orderly, predictable
• Single-skilled employees
• Hierarchical
• Big company based
• Individual-minded
• Corporate
• Local/national
• Hired for life

Now, compare that to aspects of the new work culture:

• Uncertain
• Multi-skilled employees
• Equal and flat structures
• Small business and start-up driven
• Collaborative
• “Work and lifestyle entrepreneur”
• Global
• Discrete jobs and tasks “for hire”

When comparing these two lists, I was reminded of a TED Talk by Dr. Randy Borum. He explained the changing demands we have for employees with the analogy of the hedgehog and the fox. Hedgehogs are anchored in their ways and will resize new ideas to fit their determined and singular way of thinking. In school and the working world, a hedgehog is someone who is knowledge focused, whereas a fox is someone who is learning focused. Borum further distinguishes how these two animals think using the following characteristics:

Hedgehog

• Has one organizing theory
• Deeply knowledgeable
• Self-confident
• Determined

Fox

• Can see through many lenses
• Broadly focused
• Self-critical
• Adaptive

We cannot be certain which specific skills the future will demand, but we can be certain that the ever-changing world will require people to navigate uncertain territory, often without a compass. This is why, Borum argues, the fox is more apt to succeed in a VUCA (Volatile, Uncertain, Complex, Ambiguous) future.

I agree with Borum to a point. Big business can’t rely on the same business method that grew success in the past. Large companies will have to value entrepreneurial thinkers and give employees the license to be “nimble and agile”–realizing opportunity in a timeframe that small companies can make happen — within the structure of a larger company. This will happen through partnerships, inter-company business incubators, and other novel approaches to foster ideas that promote change and growth.

Schools and colleges also need to add value to a student’s skill set by producing graduates who are agile thinkers. Today, the flipped classroom provides opportunities for students to prepare outside of class while using class time to collaborate, connect, and share their ideas with their peers as the teacher plays the role of coach. In the future, we’ll likely move beyond this model to real-life learning labs where students learn through experience; actively participate with content; match their learning with their interests, talents and abilities; and discover career paths that align with their strengths.

Dr. Peter Capelli, Director of the Center for Human Resources at the Wharton School and Professor of Education, questions the future of the hedgehog mode of thinking in his recent article, ”Focusing Too Narrowly in College Could Backfire.” Capelli says that while some students choose career paths based on economic predictions, we simply cannot predict the future. Capelli believes that choosing the wrong career path can be worse than choosing no career path. A student who gets a degree in an emerging technology that pays well today, may find herself out of work in the future when her position is replaced by the next new wave. In theory, a communications major is more nimble – like a fox – with his transferable thinking skills and has potential to be more adaptive across the industries.

Where I differ in opinion from both Borum and Capelli is that the fox and the hedgehog analogy cannot be either/or. Instead, it is both/and. You want a brain surgeon who is a hedgehog, but you also want your brain surgeon to be adaptive, communicating options as a medical partner as well as expert. Or take the student pursuing a technology degree. She can both have a successful technical career and be nimble in adapting to new technology standards in her field. We need students who possess core knowledge in math, writing, and reading skills. But employers say they also need new hires with critical thinking, interpersonal, and problem solving skills. To produce graduates who are both knowledge and learning focused, we need faculty to teach core academic skills in the context of their students’ personal and professional worlds. Without these practical connections, we will continue to produce ill-prepared graduates.

If we can foster more students and graduates who develop ingenuous ideas and are undaunted by what they don’t know, support them with mentors to coach and challenge them, and encourage within them a bold vision backed with adaptive and strategic thinking, soft and hard skills, then we will have the players who can create a thriving, dynamic economy. When students and graduates with these qualities encounter setbacks, they will have the inner faith and wherewithal to regroup and forge a new path. If they can cultivate the “dispositions of success,” a phrase from Art Costa and Bena Kallick’s new book, then they will be ready for anything in the professional world regardless of their SAT score, where they went to college, or what their first job was out of college. If we can make these shifts, we can strongly prepare students for anything they might face in a VUCA future.

In my next blog, I’ll share how we can transform our schools to reflect this both/and thinking. I invite you to answer in the comments, are we preparing our graduates for the past or the future in traditional K-12 and college classrooms

Dan Pink: How Teachers Can Sell Love of Learning to Students

In his new book To Sell is Human, author Daniel Pink reports that education is one of the fastest growing job categories in the country. And with this growth comes the opportunity to change the way educators envision their roles and their classrooms. Guided by findings in educational research and neuroscience, the emphasis on cognitive skills like computation and memorization is evolving to include less tangible, non-cognitive skills, like collaboration and improvisation.

Jobs in education, Pink said in a recent interview, are all about moving other people, changing their behavior, like getting kids to pay attention in class; getting teens to understand they need to look at their future and to therefore study harder. At the center of all this persuasion is selling: educators are sellers of ideas.

Whether a teacher is presenting to her board or pitching a crowd of 12-year-olds on why Shakespeare was a genius, it’s all the art of persuasion. Though his new book has only been out a couple of weeks, Pink said he’s already received many messages from teachers who agree that, “Yes, I sell. I sell students on poetry, on calculus, on biology.”

In fact, the business world has a lot to learn from educators: what motivates people, how to inspire people to perform well. But educators can also take a lesson from the commercial world: namely, teaching the complicated skill of finding problems. In a recent study, Pink said school superintendents rated problem-solving as the top capability they wanted to instill. Corporate executives, however, rated problem-solving as seventh on their list of attributes in employees, but rated problem identification as the single most important skill. That is, the ability to suss out issues and challenges that aren’t necessarily obvious. And this is where students could benefit from educators — learning the process of identifying a problem.

“Standardized testing: totally easy, totally cheap, and scales. Convenient for politicians and taxpayers.”

“The premium has moved from problem solving to problem finding as a skill,” Pink said. “Right now, especially in the commercial world, if I know exactly what my problem is, I can find the solution to my own problem. I don’t need someone to help me. Where I need help is when I don’tknow what my problem is or when I’m wrong about what my problem is. Problem solving is an analytical, deductive kind of skill. The phrase ‘problem finding’ comes out of research on artists. It’s more of a conceptual kind of skill.”

So how do educators help kids become problem-finders when they don’t know what the problem is or where the next one might be coming from? “A lot of people hate this word but I think we have to take it seriously, which is relevance,” Pink said. “There’s something to be said for connecting particular lessons to something in the real world.”

For instance, application of math principles, which has real relevance in the real world. “Even with my own kids, to some extent I see math has become an abstract code designed to get a right answer rather than seeing that math explains why this building is standing up, or why the traffic is going slow right now, or why the 49ers are kicking a field goal rather than going for first down.”

DANGERS OF STANDARDIZATION

One of the big topics Pink tackles in his current book is the idea of moving from transactions to transcendence — to making something personal. That’s the best way to “sell” students on what they’re learning, Pink maintains. This has been a recurring theme in education: connecting what’s taught in classrooms to students’ personal lives. But, as evidenced by current school dynamics, that’s not the way the tide is moving.

“Most of our education is heavily, heavily, heavily standardized,” Pink said. “So, 11-year-olds are all together in one room. No 10-year-olds, and certainly no 13-year-olds. And [assuming that] all of those 11-year-olds are the same, we’re going to put them all together in a 35-kid classroom. Every educator knows that doesn’t work well. Every educator knows about differentiated instruction. The idea that you treat everybody the same way is foolish, and yet the headwinds in education are very much toward routines, right answer, standardization.”

Why is it moving this way? One of the reasons, Pink said, is the “appalling” absence of leadership on this issue. “One of the things that I see as an outsider is that so much of education policy seems designed for the convenience of adults rather than the education of children,” he said. “Start time is a perfect example. Why do we do that? It’s more convenient for the teachers. Why do we have standardized testing? Because it’s unbelievably cheap. If you want to give real evaluations to kids, they have to be personalized, tailored to the kids, at the unit of one. Standardized testing: totally easy, totally cheap, and scales. Convenient for politicians and taxpayers.”

With big changes coming in the form of Common Core State Standards, some fear the idea of standardized “one-size-fits-all” will become even more deeply embedded in education policy. While mastering a core set of literacies makes sense if it can turn students into effective citizens by becoming numerate and literate, Pink said the manner in which Common Core is implemented will determine its value. If Common Core is the only curriculum presented to students, then it runs into the danger of becoming “all about cramming facts.” Knowing for a test that the 5th Amendment is about self-incrimination does not necessarily result in good citizenship.

The same principle applies to the big trend in games and learning, which sometimes results simply in rewards for rote knowledge and memorization. Games have the potential to make math more relevant or engaging, Pink said, but if they lead to standardized thinking about getting to the one right answer, that can be problematic. It’s the carrot and stick thinking vestigial of a bygone era. If the only aim of a game is for points and badges, the game has little benefit for the player. For a game to be compelling and a good source of learning, it should be capable of providing rapid, robust, regular, and meaningful feedback. Social gaming, such as Minecraft, is one instantiation of this kind of salient feedback, Pink said.

The standardized model of education is in dire need of an upgrade, producing students with skills that won’t serve them well outside the boundaries of school. Students who are driven by external rewards (grades, trophies), will be fare worse than those who are self-directed, motivated by freedom, challenge, and purpose, Pink wrote in his earlier bookDrive.

“Here’s the thing,” he said. “We have a lot of learned behavior of compliance, and hunger for external rewards and no real engagement. We have this belief that people perform better if we hit them with this endless arsenal of carrots and sticks: If-then motivators. To get to that engagement, people have to unlearn these deeply rooted habits. I defy you to find a two year old who is not engaged. That’s how we are out of the box.”

WHAT DRIVES US

As a student, Pink said he did what everyone else did — he wrote a paper for a class, wrote it neatly, on time, and for a grade. But when he started writing for the school newspaper, things shifted in his mind. He realized it would reach his peers, and suddenly he was motivated to improve his writing. The same goes for any student, he said. “Those clues are right in front of us,” says Pink.

That’s what Big Pictures Schools, a network of schools across the country, on which Pink serves as board member, are attempting to do. New students at these schools are asked questions about  their interests. They could be interested in martial arts, ballet, baseball. Then teachers take the information, and build a curriculum around those particular interests.

Another way of personalizing learning, among many others, are DIY report cards. Even a fifth-grader has the wherewithal to say, “This is what I want to learn; this is what I want to accomplish; this is what I want to get better at.” Then he can look for ways to get feedback on his performance, so he can see that he’s making progress and see that he’s getting better at something.

“An educator in upstate New York did these DIY report cards, and they changed the way he taught,” Pink said. “When students assessed themselves, they held themselves to a higher standard. This changed the way he looked at the kids.”

Explore: Dan Pink

Teaching Computers Common Sense

“Meet NEIL, an acronym for Never Ending Image Learning. NEIL’s advanced technology is the focus of an AI research project at Carnegie Melon that has it searching and comparing a wide database of images. The purpose? To see if NEIL can develop a little common sense! This Stuff article from Kevin Begos has more.”

via Stuff.co.nz

Researchers are trying to plant a digital seed for artificial intelligence by letting a massive computer system browse millions of pictures and decide for itself what they all mean.

The system at Carnegie Mellon University is called NEIL, short for Never Ending Image Learning. In mid-July, it began searching the internet for images 24/7 and, in tiny steps, is deciding for itself how those images relate to each other. The goal is to recreate what we call common sense – the ability to learn things without being specifically taught.

It’s a new approach in the quest to solve computing’s Holy Grail: getting a machine to think on its own using a form of common sense. The project is being funded by Google and the United States Department of Defense’s Office of Naval Research.

“Any intelligent being needs to have common sense to make decisions,” said Abhinav Gupta, a professor in the Carnegie Mellon Robotics Institute.

NEIL uses advances in computer vision to analyse and identify the shapes and colours in pictures, but it is also slowly discovering connections between objects on its own. For example, the computers have figured out that zebras tend to be found in savannahs and that tigers look somewhat like zebras.

In just over four months, the network of 200 processors has identified 1500 objects and 1200 scenes and has connected the dots to make 2500 associations.

Some of NEIL’s computer-generated associations are wrong, such as “rhino can be a kind of antelope,” while some are odd, such as “actor can be found in jail cell” or “news anchor can look similar to Barack Obama.”

NEIL uses advances in computer vision to analyse and identify the shapes and colours in pictures, but it is also slowly discovering connections between objects on its own.

But Gupta said having a computer make its own associations is an entirely different type of challenge than programing a supercomputer to do one thing very well, or fast. For example, in 1985, Carnegie Mellon researchers programed a computer to play chess; 12 years later, a computer beat world chess champion Garry Kasparov in a match.

Catherine Havasi, an artificial intelligence expert at the Massachusetts Institute of Technology, said humans constantly make decisions using “this huge body of unspoken assumptions,” while computers don’t. She said humans can also quickly respond to some questions that would take a computer longer to figure out.

“Could a giraffe fit in your car?” she asked. “We’d have an answer, even though we haven’t thought about it” in the sense of calculating the giraffe’s body mass.

Robert Sloan, an expert on artificial intelligence and head of the Department of Computer Science at the University of Illinois, Chicago, said the NEIL approach could yield interesting results because just using language to teach a computer “has all sorts of problems unto itself.”

“What I would be especially impressed by is if they can consistently say ‘zebra, zebra, zebra’ if they see the animal in different locations,” Sloan said of the computers.

Gupta is pleased with the initial progress. In the future, NEIL will analyse vast numbers of YouTube videos to look for connections between objects.

“When we started the project, we would not sure it would work,” he said. “This is just the start.”

Neither Mountain View, California-based Google nor the Office of Naval Research responded to questions about why they’re funding NEIL, but there are some hints. The Naval Research website notes that “today’s battlespace environment is much more complex than in the past” and that “the rate at which data is arriving into the decision-making system is growing, while the number of humans available to convert the data to actionable intelligence is decreasing.”

In other words, computers may make some of the decisions in future wars. The Navy’s website notes: “In many operational scenarios, the human presence is not an option.”

NEIL’s motto is “I Crawl, I See, I Learn,” and the researchers hope to keep NEIL running forever. That means the computer might get a lot smarter.

Or it might not.

Sweden’s Newest School System Has No Classrooms

I found this great article about new and innovative classrooms written by Jeff Dunn. It was originally posted on the website Edudemic in September 2012. Click the link to see the original article.
There’s a whole new classroom model and it’s a sight to behold. The newest school system in Sweden look more like the hallways of Google or Pixar and less like a brick-and-mortar school you’d typically see.

There are collaboration zones, houses-within-houses, and a slew of other features that are designed to foster “curiosity and creativity.” That’s according to Vittra, which runs 30 schools in Sweden. Their most recent school, Telefonplan School (see photos below via Zilla Magazine) in Stockholm, could very well be the school of the future.

Architect Rosan Bosch designed the school to encourage both independent and collaborative work such as group projects and PBL. Even the furniture is meant to get students learning. Bosch says each piece is meant to “aid students in engaging” while working.

The un-schoolness doesn’t stop with the furniture and layout though. The school has no letter grades, students learn in groups based on their level and not age.

Most of all, admission to the school is free as long as one of the child’s parents pays taxes in Sweden and the child has a ‘personal number’ which is like a social security number to our U.S. readers.

Numbers Can Lie: What TIMSS and PISA Truly Tell Us, if Anything?

“America’s Woeful Public Schools: TIMSS Sheds Light on the Need for Systemic Reform”[1]

“Competitors Still Beat U.S. in Tests”[2]

“U.S. students continue to trail Asian students in math, reading, science”[3]

These are a few of the thousands of headlines generated by the release of the 2011 TIMSS and PIRLS results today. Although the results are hardly surprising or news worthy, judging from the headlines, we can expect another global wave of handwringing, soul searching, and calls for reform. But before we do, we should ask how meaningful these scores and rankings are.

“Numbers don’t lie,” many may say but what truth do they tell? Look at the following numbers:

Table 1: Scores and Attitudes of 8th Graders in TIMSS 2011

These are the scores of 8^th graders and percentage of them saying they are confident in math and value math. Top scoring Korea has only 3% of students feeling confident in their math and 14% valuing math, in contrast is Australia with much lower scores but significantly higher percentage of students feeling confident in math and valuing math. In fact, the top 5 East Asian countries in math scores have way fewer students reporting confidence in math and valuing math than the U.S., England, and Australia, all scored significantly lower.

It gives me a headache to understand these numbers: Do they mean that even if the Korean students do not think math is important, they study it anyway? and they have a very effective education that can make people who do not value math to be outstanding in it? Or since these are 8^th graders, do they mean that after learning math for 8 years, the students feel the math they have been learning is not important in life? In the case of the United States, do they mean that American students value math but have poor math learning experiences that lead to low math achievement? Or could it be that their 8 years of math learning convinced them, at least a much larger proportion than in Korea, that math is important?

The same questions can be asked about confidence. Do the numbers mean that Korean students lack of confidence makes them study harder so they achieve better in math than their American or Australian counterparts? Or could they mean that the way math is taught in Korea made them lose confidence in math?

The data show that as students progress toward higher grades, they become less confident in their math learning. More fourth graders than eighth graders have confidence in math, for example.  Does this mean the more they learn, the less confident they become?

Or perhaps these numbers are not related at all. But the TIMSS report suggests that within countries students with higher scores are more likely to have a more positive attitude towards math, that is, a positive correlation. A negative correlation is found between countries and has been a pattern as Tom Loveless discovered in previous TIMSS. So somehow math scores, attitudes, and confidence are related. Perhaps whatever in an education system or culture that boosts math scores leads to less positive attitude and lower confidence at the same time. In this case, one needs to ask what is more important: scores, or confidence and positive attitude?

There can be other interpretations but whatever the interpretation is, these numbers show that results of TIMSS, or other international assessments such as the PISA, are a lot more complex than what the headlines attempt to suggest: Asians are great, America sucks, so do Australia and England. The TIMSS and PISA scores are perhaps worth much less than politicians and the media make of them, as the rest of this paper shows.

The Numbers Don’t Lie: A Long History of Bad Performance on International Tests

According to historical data, American education has always been bad and actually improving over the years. In the 1960s, when the First International Mathematics Study (FIMS) and the First International Science Study (FISS)[4] was conducted, U.S. students ranked bottom in virtually all categories:

11th out of 12 (8^th grade -13 year old math)

12^th out 12 (12^th grade math for math students)

10^th out 12 (12^th grade math for non-math students)

7^th out 19 (14 year-old science)

14^th out of 19 (12^th grade science)

In the 1980s, when the Second International Mathematics Study (SIMS) and Second International Science Study (SISS)[5] were conducted, U.S. students inched up a little bit, but not much:

10^th out of 20 (8^th grade-Arithmetic)

12^th out of 20 (8^th grade-Algebra)

16^th out of 20 (8^th grade-Geometry)

18^th out of 20 (8^th grade-Measurement)

8^th out of 20 (8^th grade-Statistics)

12^th out of 15 (12^th grade-Number Systems)

14^th out of 15 (12^th grade-Algebra)

12^th out of 15 (12^th grade-Geometry)

12^th out of 15 (12^th grade-Calculus)

14^th out of 17 (14 year-old Science)

14^th out of 14 (12^th grade-Biology)

12^2h out of 14 (12^th grade-Chemistry)

10^th out of 14 (12^th grade-Physics)

In the 1990s, in the Third International Mathematics and Science Study (TIMSS)[6], American test performance was not the best but again improved:

28^th out 41 (but only 20 countries performed significantly better) (8^th grade math)

17^th out 41 (but only 9 countries performed significantly better) (8^th grade science)

In 2003, in TIMSS[7] (now changed into Trends in International Mathematics and Science Study), U.S. students were not great, but again improved:

15^th out of 45 (only 9 countries significantly better) (8^th grade math)

9^th out of 45 (only 7 countries significantly better) (8^th grade science)

In 2007, U.S. improved again in TIMMS[8], although still not the top ranking country:

9^th out of 47 (only 5 countries significant better) (8^th grade math)

10^th out of 47 (only 8 countries significantly better) (8^th grade science)

Over the half century, American students performance in international math and science tests has improved from the bottom to above international average. The following figure shows the upward trend of American students’ performance in math. Because 8^th grade seems to be the only group that has been tested every time since the 1960s, the graph only includes data for 8^th grade math[9].

All the studies mentioned above have been coordinated by the International Association for the Evaluation of Educational Achievement (IEA). There is another international study, one that has gained more momentum and popularity than the ones organized by IEA. This is the Programme for International Student Assessment, better known as PISA, organized by the Organisation for Economic Co-operation and Development (OECD). PISA was first introduced in 2000 and tests 15 year olds in math, literacy, and science. It is conducted every three years. Because PISA is fairly new, so there is not a clear trend to show whether the U.S. is doing better or worse, but it is clear that U.S. students are not among the best[10]:

PISA Reading Literacy

15^th out of 30 countries in 2000

17^th out of 77 countries in 2009

PISA Math

24^th out of 29 countries in 2003

31^st out of 74 countries in 2009

PISA Sciences

21^st out of 30 countries in 2003

23^rd out of 74 countries in 2009

There are other studies and statistics, but this long list should be sufficient to prove that American students have been awful test takers for over half a century. Some has taken this mean American education has been awful in comparison to others. This interpretation has been common and backed up by media reports, scholarly books, and documentary films, for example:

1950s-1960s: Worse than the Soviet Union (1958, Life Magazine cover story Crisis in Education)[11]

1980s-1990s: Worse than Japan and others (A Nation at Risk[12], Learning Gap: Why Our Schools Are Failing And What We Can Learn From Japanese And Chinese Education[13])

2000s–: Worse than China and India (2 Million Minutes[14] (documentary film) Surpassing Shanghai)[15]

The Numbers Don’t Lie, but What Truth Do They Tell

Numbers can be used to tell stories of the past or the future. We can ask how we arrived at a certain number or what it means for the future. Asking about its past invites us to consider what we did or did not do to achieve a certain state indicated by the number. Asking about its future implications forces us to question if a certain number is desirable or meaningful. The latter must precede the former because unless the state measured by certain numbers has truly significant implications for a desirable future, the question about how we got there is practically a waste of time.

In the case of statistics from international educational assessments, the question about the future has rarely been explored. It has been assumed that these numbers indicate nations’ capacity to build a better future. And thus we must dive in urgently to learn about why others are getting better numbers than us. This assumption, however, may be wrong.

The Numbers’ Future

“Our future depends on the strength of our education system. But that system is crumbling,” reads a full-page ad in the New York Times. Dominating the ad is a graphic that shows “national security,” “jobs,” and the “economy” resting upon a cracking base of education. This ad is part of the “innovative, multitactical” Don’t Forget Ed campaign the College Board sponsored.

It is apparent America’s national security, jobs, and economy has been resting upon a base that has been crumbling and cracking for over half a century, according to the numbers. So one would logically expect the U.S. to have fallen through the cracks and hit rock bottom in national security, jobs, and economy by now. But facts seem to suggest otherwise:

The Soviet Union, America’s archrival in national security during the Cold War, which supposedly had better education than the U.S., disappeared and the U.S. remains the dominant military power in the world.

Japan, which was expected to take over the U.S. because of its superior education in the 1980s, has lost its #2 status in terms of size of economy. Its GDP is about 1/3 of America’s. Its per capita GDP is about $10,000 less than that in the U.S.

The U.S. is the 6^th wealthiest country in the world in 2011 in terms of per capita GDP[16]. It is still the largest economy in the world.

The U.S. ranked 5^th out of 142 countries in Global Competitiveness in 2012 and 4^th in 2011[17].

The U.S. ranked 2^nd out 82 countries in Global Creativity, behind only Sweden[18] in 2011.

The U.S. ranked 1^st in the number of patents filled or granted by major international patent offices in 2008, with 14,399 filings, compared to 473 filings from China[19], which supposedly has a superior education[20].

Obviously America’s poor education told by the numbers has not ruined its national security and economy. These numbers have failed to tell the story of the future.

The Numbers’ Past

The past stories of numbers lie the lessons to be learned. The problem is that there are different ways to achieve the same number, although a set of factors have been identified to explain why American students perform worse than other countries or what made some other countries achieve better numbers. As a result, the most of the factors become debatable and debated myths, half-truths, or “duh!”

Time. American students spend less time studying. President Obama noted that on average U.S. students attend class about a month less than children in other advanced countries[21] in 2010. His Secretary of Education Arne Duncan said students in China and India attend school 25 to 30 percent longer than in the U.S.[22] A 1994 report of the National Education Commission on Time and Learning established by U.S. Congress observed “Students in other post-industrial democracies receive twice as much instruction in core academic areas during high school.”[23] However a study by the Center for Public Education says “students in China and India are not required to spend more time in school than most U.S. students.”[24]

Engagement and Commitment. American students, schools, parents, and governments don’t take school-based learning as seriously as other top performing countries. Not only students in other countries spend more time in school, “the formidable learning advantage Japanese and German schools provide to their students is complemented by equally impressive out-of-school learning,” noted the National Education Commission on Time and Learning in 1994[25]. “Compared with other societies, young people in Shanghai may be much more immersed in learning in the broadest sense of the term. The logical conclusion is that they learn more…” writes an OECD report explaining Shanghai’s outstanding PISA scores[26]. But the same report immediately notes “what they learn and how they learn are subjects of constant debate.”

Curriculum, Standards, Gateways, and Tests. The U.S. does not have a better (more focus, rigor, and coherence) common curriculum with high standards across the nation and an instructional system with clearly marked transition points. “…standards in the best-performing nations share the following three characteristics [focus, rigor, and coherence] that are not commonly found in U.S. standards,” says a report that calls for international benchmarking by the National Governors’ Association[27].  “Virtually all high-performing countries have a system of gateways marking the key transition points…At each of these major gateways, there is some form of external national assessment,” writes Marc Tucker in Surpassing Shanghai: An Agenda for American Education Built on the World’s Leading Systems (Tucker, 2011, p. 174). But Ontario, a top PISA performer does not, admits Tucker and schools in Finland, a much admired high performer on the PISA, “is a “standardized testing-free zone,”[28] writes Diane Ravitch.

Teachers and Teacher Education. American teachers are not as smart to begin with and are less well prepared than their counterparts in high performing countries. For example, while 100% of teachers in top performing countries –Singapore, Finland and South Korea — are recruited form the top third college graduates, only 23% are from the top third in the U.S., according to a study by the consulting firm McKinsey & Co[29].  Teachers in these top performing countries are also better trained, supported, and motivated before, during, and after taking the teaching job. This is one of the “duhs.”

Inequity and poverty. There is more social economic disparity among U.S. students and higher levels of poverty in the U.S. than other countries. “U.S. students in schools with 10% or less poverty are number one country in the world,” says a report of the National Association of Secondary School Principals[30]. The report establishes a direct connection between PISA performance and poverty and says the U.S. has the largest number of students living in poverty. But others disagree. “The U.S. looks about average compared with other wealthy nations on most measures of family background,” says the report from the National Governor’s Association, “Moreover, America’s most affluent15-year-olds ranked only 23rd in math and 17th in science on the 2006 PISA assessment when compared with affluent students in other industrialized nations.”[31]

There are of course other suggestions from access to natural resources[32] to cultural homogeneity and from sampling bias to parenting styles. Regardless, how each country achieved their international scores is not nearly as straightforward as the numbers themselves, making international learning a very difficult task.

The task becomes perhaps even more difficult, when the issues of economic, cultural, societal, and political contexts are considered. What’s more, learning from others may become not so desirable for the U.S. considering the fact that the test scores have not significantly affected America’s national security and economy. Moreover in the final analysis, since countries that have shown better numbers in tests have not performed necessarily better than the U.S., the U.S. education may have something to offer others.

The Numbers Don’t Lie, but Some Are Missing: Two Paradigms of Education

The fact the U.S. as a nation is still standing despite of its abysmal standing on international academic tests for over half a century begs two questions:

Is education as important to a nation’s national security and economy as important as believed?

If it is, are the numbers telling the truth about the quality of education in the U.S. and other nations?

If the answer to the first question is “no,” we need to disconnect the automatic association between test scores and education. In other words, the numbers don’t really measure education, at least not the entire picture of the education needed to produce citizens to build strong and prosperous economies.

In my latest book World Class Learners: Educating Creative and Entrepreneurial Students[33], I identified two paradigms of education: employee-oriented and entrepreneur-oriented.  The employee-oriented paradigm aims to transmit a prescribed set of content (the curriculum and standards) deemed to be useful for future life by external authorities, while the entrepreneur-oriented aims to cultivate individual talents and enhance individual strengths. The employee-oriented paradigm produces homogenous, compliant, and standardized workers for mass employment while the entrepreneurial-oriented education encourages individuality, diversity, and creativity.

Although in general, all mainstream education systems in the world currently follows the employee-oriented paradigm, some may not be as effectively and successfully as others. The international test scores may be an indicator of how successful and effective the employee-oriented education has been executed. In other words, these numbers are measures of how successful the prescribed content has been transmitted to all students. But the prescribed content does not have much to do with an already industrialized country such as the U.S., whose economy relies on innovation, creativity, and entrepreneurship. As a result, although American schools have not been as effective and successful in transmitting knowledge as the test scores indicate, they have somehow produced more creative entrepreneurs, who have kept the country’s economy going. Moreover, it is possible that on the way to produce those high test scores, other education systems may have discouraged the cultivation of the creative and entrepreneurial spirit and capacity.

Unfortunately there are few numbers that directly provide the same kind of comparison as TIMSS and PISA on measures of creativity and entrepreneurship, making it difficult to forcefully prove that American education indeed produce more creative and entrepreneurial talents. A piece of data I have found from the Global Entrepreneurship Monitor study suggests a significant negative relationship between PISA performance and indicators of entrepreneurship. The Global Entrepreneurship Monitor, or GEM, is an annual assessment of entrepreneurial activities, aspirations, and attitudes of individuals in more than 50 countries. Initiated in 1999, about the same time that PISA began, GEM has become the world’s largest entrepreneurship study. Thirty-nine countries that participated in the 2011 GEM also participated in the 2009 PISA, and 23 out of the 54 countries in GEM are considered “innovation-driven” economies, which means developed countries.

Comparing the two sets of data shows clearly countries that score high on PISA do not have levels of entrepreneurship that match their stellar scores. More importantly, it seems that countries with higher PISA scores have fewer people confident in their entrepreneurial capabilities. Out of the innovation-driven economies, Singapore, South Korea, Taiwan, and Japan are among the best PISA performers, but their scores on the measure of perceived capabilities or confidence in one’s ability to start a new business are the lowest. The correlation coefficients between scores on the 2009 PISA in math, reading, and science and 2011 GEM in “perceived entrepreneurial capability” in the 23 developed countries are all statistically significant[34].

Anecdotally, Vivek Wadhwa, president of Academics and Innovation at Singularity University, Fellow at Stanford Law School and Director of Research at Pratt School of Engineering at Duke University, wrote in Business Week in response to the latest PISA rankings:

The independence and social skills American children develop give them a huge advantage when they join the workforce. They learn to experiment, challenge norms, and take risks. They can think for themselves, and they can innovate. This is why America remains the world leader in innovation; why Chinese and Indians invest their life savings to send their children to expensive U.S. schools when they can. India and China are changing, and as the next generations of students become like American ones, they too are beginning to innovate. So far, their education systems have held them back.[35]

But there again are no numbers to prove these. However, other countries, particularly the high scoring Asian countries have all been reforming their education systems to be more like that in the U.S., as I have discussed in my book Catching Up or Leading the Way: American Education in the Age of Globalization[36].

Conclusions

I have put forth a lot of numbers of different sorts from a variety of sources. Taken together, these numbers suggest to me the following:

So far all international test scores measure the extent to which an education system effectively transmits prescribed content.

In this regard, the U.S. education system is a failure and has been one for a long time.

But the successful transmission of prescribed content contributes little to economies that require creative and entrepreneurial individual talents and in fact can damage the creative and entrepreneurial spirit. Thus high test scores of a nation can come at the cost of entrepreneurial and creative capacity.

While the U.S. has failed to produce homogenous, compliant, and standardized employees, it has preserved a certain level of creativity and entrepreneurship. In other words, while the U.S. is still pursuing an employee-oriented education model, it is much less successful in stifling creativity and suppressing entrepreneurship.

The U.S. success in creativity and entrepreneurship is merely an accidental by product of a less successful employee-oriented education, which is far from sufficient to meet the coming challenges brought about by globalization and technological changes. Thus in a sense, the U.S. education is in turmoil, inadequate, and obsolete, but it has to move toward more entrepreneur-oriented instead of more employee-oriented.

[1] http://dropoutnation.net/2012/12/11/americas-woeful-public-schools-timms-sheds-light-on-the-need-for-systemic-reform/

[2] http://online.wsj.com/article/SB10001424127887324339204578171753215198868.html

[3] http://www.washingtonpost.com/local/education/us-students-continue-to-trail-asian-students-in-math-reading-science/2012/12/10/4c95be68-40b9-11e2-ae43-cf491b837f7b_story.html

[4] Data source: U.S. National Center for Educational Statistics: http://nces.ed.gov/pubs92/92011.pdf

[5] Data source: U.S. National Center for Educational Statistics: http://nces.ed.gov/pubs92/92011.pdf

[6] Data source: U.S. National Center for Educational Statistics: http://nces.ed.gov/pubs99/1999081.pdf

[7] Data source: U.S. National Center for Educational Statistics: http://nces.ed.gov/timss/results03.asp

[8] http://nces.ed.gov/timss/results07.asp

[9] Since SIMS scores were reported in sub domains, I chose the lowest performance area for the U.S. students: Measurement.

[10] Data source: http://www.oecd.org/pisa/

[11] http://goo.gl/pAgnQ

[12] http://datacenter.spps.org/uploads/SOTW_A_Nation_at_Risk_1983.pdf

[13] http://books.google.com/books/about/Learning_Gap.html?id=HIfBn5W6LMcC

[14] http://www.2mminutes.com/

[15] http://www.amazon.com/Surpassing-Shanghai-American-Education-Leading/dp/1612501036

[16] Data source: International Monetary Fund: http://goo.gl/r7SFQ

[17] http://www3.weforum.org/docs/WEF_GCR_Report_2011-12.pdf

[18] Data source: http://www.theatlanticcities.com/jobs-and-economy/2011/10/global-creativity-index/229/

[19] Data Source: Chinese Innovation is a Paper Tiger http://online.wsj.com/article/SB10001424053111904800304576472034085730262.html?mod=googlenews_wsj

[20] Students from Shanghai China scored 1^st on the PISA in all three subjects (math, reading, and sciences) in the last round of PISA released in 2010.

[21] http://today.msnbc.msn.com/id/39378576/ns/today-parenting/#.UEPqb2ie7sc

[22] http://www.centerforpubliceducation.org/Main-Menu/Organizing-a-school/Time-in-school-How-does-the-US-compare

[23] http://www2.ed.gov/pubs/PrisonersOfTime/Lessons.html

[24] http://www.centerforpubliceducation.org/Main-Menu/Organizing-a-school/Time-in-school-How-does-the-US-compare

[25] http://www2.ed.gov/pubs/PrisonersOfTime/Lessons.html

[26] http://www.oecd.org/countries/hongkongchina/46581016.pdf

[27] http://www.corestandards.org/assets/0812BENCHMARKING.pdf

[28] http://www.nybooks.com/articles/archives/2012/mar/08/schools-we-can-envy/?pagination=false

[29] http://mckinseyonsociety.com/closing-the-talent-gap/

[30] http://nasspblogs.org/principaldifference/2010/12/pisa_its_poverty_not_stupid_1.html

[31] http://www.corestandards.org/assets/0812BENCHMARKING.pdf

[32] http://www.oecd.org/education/preschoolandschool/programmeforinternationalstudentassessmentpisa/49881940.pdf

[33] http://zhaolearning.com/world-class-learners-my-new-book/

[34] http://zhaolearning.com/2012/08/16/doublethink-the-creativity-testing-conflict/

[35] http://www.businessweek.com/technology/content/jan2011/tc20110112_006501.htm

[36] http://zhaolearning.com/2009/11/14/3/

This is a repost from the blog of Dr. Yong Zhao.

USA Fairs poorly AGAIN in NAEP | Jeff Piontek wants to know your thought as to why.

In 2011, the National Assessment of Educational Progress (NAEP) tested 122,000 eighth grade students in their knowledge of science according to the 2011 NAEP Science Framework. Students are tested in their knowledge of science and their ability to work problems in three science areas: physical science, life science, and the Earth and space sciences. The test covered 50 states, the District of Columbia and the Department of Defense schools. Students’ test scores placed them in one of four categories: Below Basic, Basic, Proficient, and Advanced. The terms Basic, Proficient, and Advanced are defined as:

• Basic denotes partial mastery of prerequisite knowledge and skills that are fundamental for proficient work at each grade.
• Proficient represents solid academic performance. Students reaching this level have demonstrated competency over challenging subject matter.
• Advanced represents superior performance.

While the national report card for eighth graders does show improvement, the results of the sample suggests that the nation as a whole has more students in the Below Basic category than any other:

• Below Basic        36%
• Basic                      34%
• Proficient            29%
• Advanced              2%

The achievement-level results in the eighth-grade NAEP science scores for the years 2009 and 2011 are:

• At or above Basic went from 63% to 65%
• At or above Proficient went from 30% to 32%
• The number of students in Advanced stayed the same each year.

Here are some sample questions by science content area and difficulty level for grade eight students:

Basic

Physical Science

• Describe the energy transfer between two systems
• Read a motion graph

Earth and Space Sciences

• Draw a conclusion based on fossil evidence
• Predict a geological consequence of tectonic plate movement
• Identify the mechanisms of a weather pattern

Life Science

• Recognize a factor that affects the success of a species
• Predict the effect of an environmental change on an organism
• Explain an experimental setup to study populations of organisms
• Recognize how plants use sunlight

Physical Science

• Identify an example of kinetic energy

Proficient

Earth and Space Sciences

• Explain the effects of human land use on wildlife
• Predict a lunar phenomenon
• Relate characteristics of air masses to global regions
• Identify a source of energy for the Earth’s water cycle
• Predict the long-term pattern in the volcanic activity of a region
• Investigate the magnetic properties of some common objects

Physical Sciences

• Select and explain the useful properties of a material used in an industrial process
• Identify the atomic components of the molecule
• Determine a controlled variable in a chemistry investigation
• Recognize an effect of electrical forces

Life Sciences

• Identify the main sources of energy for certain organisms
• Select and explain graph types and draw graphs from data that compare insect behaviors
• recognize that plants produce their own food
• Describe the competition between two species
• Identify a function of a human organ system

Advanced

Earth and Space Sciences

• Predict and explain a weather pattern due to collision of air masses
• Explain the formation of a rock based on its features

• Draw a conclusion about soil permeability using data

Physical Science

• Describe the evidence for chemical change
• Identify chemically similar elements on the Periodic Table
• Explain a change in energy due to friction

Life Sciences

• Select and explain graph types and draw graphs from data that compare insect behaviors
• Form a conclusion based on data about the behavior of an organism

The daily scoop is out!!!

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