Many math teachers around the country have adjusted their expectations for students as a result of the Common Core State Standards. But a pilot professional-development program is going above and beyond the new benchmarks by teaching small groups of elementary teachers in three states to teach a math skill that鈥檚 typically been reserved for high school and college students.
The three-year project, known as 鈥淚mmersion鈥 and funded by a $1.3 million grant from the National Science Foundation, is focused on mathematical modeling.
Young children start using physical models in mathematics as soon as they can count. But mathematical modeling is something different and more complex: It鈥檚 the process of taking an open-ended, multifaceted situation, often from life or the workplace, and using math to solve it.
鈥淪ometimes making a mathematical argument helps you make decisions that seem too big or messy to understand,鈥 explains Rachel Levy, an associate professor of mathematics at Harvey Mudd College in Claremont, Calif., who is leading the Immersion project.
The idea is to get young students seeing how mathematics can be applied to everyday life鈥攊n essence, an extension of the common standards鈥 push for critical thinking and application.
Here鈥檚 an example: A group of students wants to buy pizza for a class party. The teacher asks them to consider the different ways they might select a pizza place (cost, taste, proximity to school, etc.), and to come up with a mathematical argument to justify which pizza place is the best. The students then create a method, or model, that other classes could use for deciding on a pizza place as well.
Unlike much of what students learn in math class, these big, messy problems tend to have multiple entry points and no single right answer.
鈥淭raditionally, students are sort of told and shown everything they鈥檙e supposed to learn鈥攕olve this kind of problem this way, and so on,鈥 said Martin Simon, a mathematics education professor at New York University, who is not involved with the NSF project. 鈥淏ut mathematical modeling is a very different kind of process. ... It鈥檚 engaging students in the process of thinking about a situation and trying to find ways to mathematize that situation.鈥
Because mathematical modeling requires higher-level thinking, decisionmaking, and synthesis of various skills, it鈥檚 not generally taught to younger pupils. In fact, according to Simon, it hasn鈥檛 historically been part of K-12 teaching at all.
Common-Core Connections
The common-core standards have changed that, though, by mentioning modeling in several ways. For example, one of the eight Standards for Mathematical Practice鈥攖he overarching standards that describe the behaviors of 鈥減roficient鈥 math learners鈥攕ays that students should 鈥渕odel with mathematics.鈥
Teachers participating in the Immersion program created a video to illustrate for other elementary teachers and students what mathematical modeling looks like.
Produced and copyrighted 2015 by the IMMERSION PROGRAM at Harvey Mudd College
According to William McCallum, a lead writer of the common-core math standards, that statement was intended to encompass conceptual mathematical modeling (and not just using physical models). Children can begin doing simple word problems, which he calls 鈥渂aby modeling,鈥 as young as kindergarten.
鈥淏ut the full modeling cycle involves some powers of discrimination and decisionmaking that we don鈥檛 normally attribute to kids of that age,鈥 McCallum said in an email. Under the common core, students aren鈥檛 expected to go through the full modeling cycle until they get to high school.
There鈥檚 no doubt the Immersion program, conducted through university-district partnerships, is ambitious in introducing modeling lessons to elementary-level teachers. But Simon said getting students thinking earlier about how to justify choices with mathematics is important.
鈥淭hat鈥檚 how students learn what mathematics is really about,鈥 he said, 鈥渋nstead of thinking math is about doing 50 long-division problems and then going to high school and [having teachers] trying to change their minds.鈥
Over the summer, two dozen K-6 teachers from the Fairfax County school district in Virginia gathered at George Mason University for a week鈥檚 worth of training on mathematical modeling.
The group was one of three such cohorts, with public school teachers in Bozeman, Mont., and Pomona, Calif., also meeting that month at local universities for similar training. All the teachers had to apply and be selected to take part in the planned yearlong program.
Padmanabhan Seshaiyer and Jennifer Suh, both mathematics professors at George Mason, opened the session by asking the teachers to brainstorm the kinds of problems they鈥檝e had to solve in their own lives recently. On poster paper, the teachers wrote queries such as:
Is it worth driving farther to get cheaper gas?
Should I fix up my house before I sell it? What rooms should I do?
We鈥檙e driving to Atlanta with a 2-year-old and a beagle鈥攚hen is the best time to leave?
The process of taking a real-world situation and modeling it mathematically is a new concept for many elementary educators. Rachel Levy, who directs the NSF鈥檚 Immersion project, says teachers can ask themselves the following questions to ensure they鈥檙e on the right track when doing a classroom modeling activity.
鈥 Did the students start with a big, messy, real-world problem?
鈥 Did the students ask questions and then make assumptions to define the problem?
鈥 Are they choosing mathematical tools to solve the problem?
鈥 Are they using the mathematical tools to solve the problem?
鈥 Are the students communicating with someone who cares about the solution?
鈥 Have they explained if/when their answer makes sense?
鈥 Have they tested their model/solution and revised if necessary?
SOURCE: Rachel Levy, Harvey Mudd College
The exercise served to get the teachers thinking about how often they encounter problems that might benefit from mathematical modeling. The participants then tried a problem together. They looked at a larger room in the building that had been split into two smaller classrooms, with a temporary wall and door connecting them. They worked on figuring out how the new configuration of the room would affect the amount of time it takes people to exit in the event of an emergency.
As they worked, Seshaiyer asked the teachers to identify their 鈥渁ssumptions and constraints,鈥 words typically used in engineering classes, referring to the factors they believe to be true and those that limit their solutions. For example, an assumption might be that the doors to the hallway could not be moved. The number of doors and their positions would be constraints.
One teacher suggested testing the problem with a prototype鈥攑utting marbles into a box designed like the room and tilting it to see how they exit with and without the extra wall.
Through the Immersion project, teachers will meet periodically throughout the school year in groups of four or five to do 鈥渓esson study"鈥攁 collaborative teaching-improvement process with origins in Japan. The groups will choose a modeling problem, devise lesson plans around it, and predict how students will solve the problem, as well as the kinds of mistakes they鈥檒l make. After doing the modeling problem with their classes, the team will meet again to debrief on what worked and didn鈥檛 work with students.
鈥淗aving all those heads together to anticipate what kids will do will be a benefit,鈥 said Brian Kent, a math-resource teacher at Weyanoke Elementary School in Fairfax who took part in the professional development.
Content-Knowledge Concerns
Spencer Jamieson, an elementary-mathematics specialist for Fairfax County, emphasized that modeling is just one of many tactics teachers will use in the classroom鈥攁nd that students still do need to learn basic computation and other math skills. Jamieson, who is the project liaison for his district, recommends elementary teachers 鈥渟tart off small,鈥 perhaps doing just one modeling problem with students per quarter.
But mathematical modeling is not an easy concept to understand in itself, much less to explain to early learners.
Ensuring that elementary-math teachers鈥攎ost of whom are generalists鈥攈ave the content knowledge necessary to teach mathematical modeling is 鈥渁 huge concern,鈥 said Simon of New York University, 鈥渁nd we have not yet addressed elementary-math teachers鈥 content knowledge in any effective way.鈥
鈥淥n the other hand,鈥 he said, 鈥淚 would not say let鈥檚 do more impoverished math teaching because of their more limited background.鈥
Experts caution that mathematical-modeling problems for the classroom should be chosen with care.
鈥淵ou really need to anticipate how students are going to enter into the modeling problem, and you need to be very clear on what are the mathematical targeted goals you want kids to learn and develop,鈥 said Karen Koellner, an associate professor at Hunter College in New York City who teaches courses in mathematics education. (While not involved in the Immersion project, Koellner did similar work providing professional development in modeling for middle school teachers in the early 2000s.)
Teachers also need to know how to get students who stray during the modeling process back on track, said Koellner. 鈥淲hat are the probes and questions you鈥檙e going to ask that don鈥檛 direct kids in a particular way but cause them to rethink what they鈥檙e doing?鈥 she said. When the teacher sees students going in the wrong direction, he or she should ask questions that cause them 鈥渁 little cognitive dissonance.鈥
That sort of questioning takes preplanning and an upfront analysis of where misconceptions may occur, experts say.
During the workshop at George Mason, Levy, the project leader, showed how difficult modeling can be in the moment. She posed a student solution to the exit problem that seemed logical, but was mathematically unsound.
Once the teachers discovered the mistake鈥攖he student had confused fractions and ratios鈥攁 long conversation ensued about whether it was worth explaining what ratios were if the student hadn鈥檛 reached that standard. The teachers ultimately couldn鈥檛 come to a consensus on how to respond.
鈥淚t鈥檚 hard, right? I don鈥檛 want to pretend that it鈥檚 easy,鈥 Levy told the group. 鈥淓lementary students are capable of proving conundrums that are incredibly difficult to untangle. But that鈥檚 why mathematical modeling can lead to incredibly rich conversations about what makes sense and why.鈥
