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GENERATING KNOWLEDGE AND PASSION
FOR SCIENCE AND MATHEMATICS
THROUGH MODELING
Atkinson et al. (2007). Addressing the
STEM Challenge by Expanding SM&SHS.
A recently released report1 addressesd the
challenges America faces in STEM fields. The
report suggested that specialty science and math
schools have demonstrated an ability to educate
future scientists and engineers. However, even
these schools face challenges, which include
public support, funding, and quality curriculum.
With respect to quality curriculum, how have we at
the North Carolina School of Science and
Mathematics (NCSSM) approached this
particular issue?
Our approach has been through modeling because
it provides opportunities for students to engage
real-world applications that are both challenging
and motivating.
CALCULUS

Standard set of optimization problems
Finding the maximum volume of an open box
constructed from a rectangular sheet of cardboard.
 Rectangular plot of land bounded by a river/cliff and
3 pieces of fence.
 Minimum distance between a stationary object and
some other object that travels along a given path.

WHAT DO STUDENTS/TEACHERS GAIN?

Students
Practice with derivatives and solving equations.
 Superficial understanding.
 Passion?


Teachers

Minimal information about students’ ability to think.
COMMON STUDENT QUESTIONS
•
•
•
Who makes up these problems?
Why do I want to know that?
When will I use this?
WHAT’S GAINED FROM A
MODELING APPROACH?
A deeper appreciation for mathematics.
 Exercises technical writing and communication
skills.
 Generates enthusiasm and interest in the
applications of mathematics.

HOW DOES ONE BEGIN?
Do small labs, which provide opportunities to
work with software (Mathcad) and basic ideas.
 Identify independent and dependent variables.
 If a max/min is known, what should graph look
like?
 Then what information can we obtain about the
characteristics of the function?
 Move on to a bigger project in groups of 3 to 4.

EXAMPLE
Researchers study the way salmon swim upstream
to spawn. In theory, the energy the salmon
expend in swimming against the current depends
on the speed at which they swim as well as the
amount of time they spend swimming. We have
a function of two variables, but we can rewrite
this as a function of one variable since time is
equal to distance divided by rate.
The graph begins with a point that we know to be
the minimum. Based on that, what should the
graph look like?
Now, what function could possibly model this
behavior? What do we need to consider?
Distance the fish has to swim.
 Fish will expend a lot of energy if it swims
slightly faster than the water.
 Fish will also expend a lot of energy if it swims
really fast.
 Some constant of proportionality.

D
p
E (v)  cv
vr
c is a positive constant of proportionality
 D is the distance the fish has to swim
 r is the rate of the water
 v is the velocity of the fish
 p>0

SUBWAY DESIGN
Suppose that you were building a new subway
system. How far apart would you place the
stations in order to minimize the time that a
typical subway user takes to get from his point of
origin to his final destination? Creating a model
that will allow you to answer that question is the
purpose of this investigation. Consider these two
questions before you begin creating your model.
QUESTIONS TO PONDER?
What is/are the advantage(s) (in terms of a
commute of shorter duration) of having subway
stations close together?
 What is/are the advantage(s) (in terms of a
commute of shorter duration) of having subway
stations far apart?

Note: The previous slides are only a portion of
the problem we give to students. They are given
guidelines (See Subway Design Student Version),
which may be tailored to give more or less
guidance.
After reading the details of the problem, students
then are asked to identify the independent and
dependent variables as well as make some
assumptions. Word of caution: Some students
can go overboard with the assumptions and
create a situation they have difficulty modeling.
KEEP IT SIMPLE!!!
TRAFFIC FLOW
Everyone has at some time been on a multi-lane
highway and encountered road construction that
required the traffic to occupy only one lane each
way. Naturally, the Department of
Transportation would like to maximize the flow
of traffic through this stretch of highway. What
speed limit would be set for such a stretch of road
to ensure the greatest traffic flow while also
maintaining safety? In this investigation, you
will explore how you might model traffic flow and
answer a number of questions regarding this
using calculus.
INFECTIOUS DISEASE
How does a disease like SARS spread? Groups to
be considered are “people currently infected”,
“people not infected now but who are
susceptible”, “people who had the disease but
recovered” and “people who died from SARS”.
Once you have this modeled, how can you use the
model to think about how to control the spread of
the disease? A nice feature of this investigation
is real data on spread of various recent diseases.
POLLUTION IN THE GREAT LAKES
Water flows from Lake Huron to Lake Erie to
Lake Ontario to the Atlantic Ocean. If a factory
on any lake dumps pollution into the water, the
“down stream” lakes are also polluted. What’s
the long term behavior of this system? A nice
enhancement to this investigation is to learn a
new technique of integration so you can solve the
system analytically.
CHALLENGES FOR EDUCATORS?
Problems suitable to level of students.
 Finding new problems.
 Match to student interests.

Richard Noble III
(919) 416-2741
[email protected]