Undergraduate Research

SUMMER 2012 APPLICATIONS

NOTE THE NEW MATH DEPT DEADLINE!

Summer 2012 NSERC UNDERGRADUATE STUDENT RESEARCH AWARDS
DEPARTMENT OF MATHEMATICS - SIMON FRASER UNIVERSITY

These NSERC awards are valued at $4,500 for a minimum of sixteen weeks. The University will supplement this amount from other sources making salaries of at least $1,400 per month plus benefits. These awards are provided to encourage undergraduate student interest in research and in graduate studies.

Below are brief descriptions of research projects in mathematics from faculty members who wish to supervise qualified undergraduate students. Unless otherwise specified, each project is available to one student only.

WHO SHOULD APPLY:

Undergraduate students with strong records (B- minimum) in mathematics courses who are Canadian citizens or permanent residents are eligible. Students must have obtained a cumulative average of at least B- over the entire period of undergraduate studies. Please note that this average is a minimum requirement and the cut-off point is often higher.

To hold an award, you must have completed all course requirements of at least the first year of your bachelor's degree program, and must not have started a program of graduate studies. Also, you should be a full-time student at the time of application. Female students or students of aboriginal descent are particularly encouraged to apply.

HOW TO APPLY:

NSERC guidelines and application forms are on the NSERC website.

Please be sure to review full eligibility criteria on the NSERC website.

NB: Changes have been made to the application process.

To do prior to 01 February, 2012 ***NB: NEW DEADLINE***

Interested eligible students should contact the supervisor with regards to the project they would like to work on.
Students must create an NSERC Online Account and complete the application for an Undergraduate Student Research Award Form 202 (Part I) & upload scanned copies of their official transcripts.
Students must submit to the department, the following: printed Form 202 (Part I), photocopies of transcripts, their NSERC Online Reference # and 2 reference letters.***

***If you are chosen, you will be notified within 3 business days.***

To do prior to 07 February, 2012

Once chosen, the student must email the selected supervisor and have them complete Form 202 - Part II; the supervisor will need to know the applicant’s reference number to do so.
The proposed supervisor must complete Form 202 Part II online and submit it online only. The supervisor must submit the form online before the applicant will be able to submit their form.
The applicant verifies their application and submits online prior to 07February , 2012

*** NB: Reference letters must be requested by 18 January, 2012 and must arrive at the Math Department prior to 01 February, 2012. Please have reference letters addressed to Dr. Manfred Trummer.

**Note: while we do our best to match students up with their preferred projects / supervisors, we cannot guarantee a preferred match due to the competitive nature of the awards.

Please also arrange to have two reference letters sent to:

Dr. Manfred Trummer, Chair
Department of Mathematics
8888 University Drive
Simon Fraser University
Burnaby, B.C. V5A 1S6

If you have questions, please contact JoAnne Hennessey, Acting Secretary to the Chair, Mathematics voice: 778.782.4238 / mcs@sfu.ca

SUMMER 2012 NSERC USRA PROJECT DESCRIPTIONS

NB: All projects will be posted after 10 January, 2012

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Joint Supervisors: Adam Oberman and Paul Tupper

Project: nonlocal diffusions and mathematical finance (2 students)

A classic Nobel winning problem by Merton is the design of optimal portfolios.

The solution of this problem is based on the concept of stochastic control: optimizing your expected utility in a random environment.

Newer models take into account nonlocal effects, which model the fact that stock prices sometimes make unexpected large jumps.

This project will involve learning some backgrounds and performing simulations.

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Joint Supervisors: Adam Oberman and Razvan Fetecau

Project: Flocking behaviour and nonlinear equations (2 students)

The behaviour of flocking birds and insects has been used as a model for a variety of topics, such as reputation management on the internet, political opinion forming, and controlling drone planes. This project will involve learning background material on ODE and PDEs for modeling flocking, and performing simulations.

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Surpervisor: Jason Bell

Project: Power series satisfying a homogeneous linear differential equation

This project looks at the following question: If a power series with integer coefficients and finite radius of convergence is the solution to a non-trivial homogeneous linear differential equation, does it follow that it is the diagonal of a multivariate rational function? At the moment this is known only in the case that the power series is algebraic and for some other special classes. The background needed is some number theory and algebra. Applicants should be able to do some programming and should also be familiar with LaTeX.

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Supervisor: Jonathan Jedwab

Project: Combinatorial Problems Arising in Digital Communications

The project will involve the study of combinatorial problems arising in digital communications. See here for background on the general area of research, and here for examples of previous USRA projects. Students should have completed MACM 201, and preferably have some programming experience. However, the most important attributes are enthusiasm, persistence, and a willingness to learn new skills.

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Supervisor: Paul Tupper

Project: What is the diversity analogue of uniform spaces?

Topologies and metric spaces are two fundamental notions of space in
mathematics. Every metric space has a standard topology associated
with it. However, it turns out that intermediate between topologies
and metric spaces there are uniform spaces (also known as
uniformities) which do not have a metric but still have the concept of
uniform convergence.

On the other hand, my colleague David Bryant and I have developed a
generalization of metric spaces called diversities. In a diversity,
any finite set of points has associated with it a measure of how
"diverse" it is. For pairs of points, this reduces to a metric.

We want to know what is the analogue to uniform spaces for
diversities. The student will work to answer this question by
familiarizing themselves with the concepts of topologies, metric
spaces, uniform spaces, and diversities, and the relations between
them. Category theory may play an important role in discovering the
correct analogue, but no prior knowledge of this is required.

The only prerequisite for this project is good performance in Math 320
or equivalent.

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Supervisor: Manfred Trummer

Project: High-order methods for differential equations

This project investigates spectral methods and radial basis function methods for solving differential equations with a focus on stability and adaptivity. Includes theory, numerical experiments and applications. Requires basic familiarity with Matlab.

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SUpervisors: Peter Borwein and Vahid Dabbaghian

Project: Application of Fuzzy Logic in Complex Social Systems

Human decision-making behavior is a fuzzy system. Therefore, fuzzy models, and in particular Fuzzy Cellular Automata (FCA), can be applied for better understanding the dynamic of urban transformations, such as infectious diseases, crimes, and other social disorders, among individuals in a high risk society. The models will be developed in the software package Matlab, so we expect that students have some computer programming skills.

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Supervisor: Karen Yeats

Project: c2 invariants of Feynman graphs.

The c2 invariant of a scalar Feynman graph is an arithmetic invariant which gives information about the Feynman integral but is much easier to compute. There are many basic things which we do not know about this invariant. This project is to compute some examples and so develop some reasonable conjectures.

The student should have a taste for discrete problems and some background either in discrete math or in number theory. No background in quantum field theory is necessary. The project will entail some programming.

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Professor Michael Monagan

Project: Computational Algebra Projects

The Computer Algebra Group at SFU is a group of faculty and students
interested in computer mathematics and systems like Maple and Magma.
We presently have a MITACS project, a joint research project with the
Maple company where we are developing algorithms and software for
doing mathematics. For example, the Maple company asked us in 2004
to develop a package for graph theory and now they would like us to
develop one for computational group theory.

We are looking for one student, a mathematics student or a computing
student, to work on one or both of the following projects.

Project 1. Developing a Maple package for computations in finite groups.

Students need to have taken a first course in group theory,
e.g. MATH 341 Groups at SFU. Students need basic programming
skills and an interest in finite groups.

Project 2. Extending Maple's graph theory package.

Students need to have taken a first course in graph theory,
e.g. MATH 345 Graph Theory at SFU, or a computing course on
graph theory algorithms, e.g. CMPT 405 Design and Analysis of
Computing Algorithms at SFU. Students need basic programming
skills and an interest in graph theory algorithms.

Both projects will be done in Maple. Familiarity with Maple would
be helpful but it is not essential. However, both projects will
involve a significant amount of programming and experimentation.
To see what summer NSERC students have done in previous years,
please take a look at the posters at

http://www.cecm.sfu.ca/research/posters.shtml

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Project Title: Computing Flow Polynomials

Supervisors: Bojan Mohar and Jessica McDonald

There are many interesting open conjectures about so-called ``flow polynomials'' of graphs (see eg [1], [2], [3]). This project will be about computing these polynomials for certain graphs, particularly graphs where all vertices have degree three. The student will look for explicit formulas for flow polynomials of graph families (eg. prisms, generalized Petersen graphs, etc.), and write a computer program based on a known recursive formula called the contraction-deletion formula (see [1]). With this project, we would hope to provide good evidence for conjectures about flow polynomials (or perhaps even disprove one).

[1] Page 563 of Graph Theory by J. A. Bondy and U.S. R. Murty (Springer, 2000)

[2] http://garden.irmacs.sfu.ca/?q=op/real_roots_of_the_flow_polynomial

[3] http://en.wikipedia.org/wiki/Nowhere-zero_flows

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Supervisor: Mary-Catherine Kropinski

Title: Integral Equation Methods and Fluid Dynamics (2 students or 1 student who chooses 1 project)

Integral equation methods have become increasingly popular in computational simulations involving the solution to partial differential equations (PDEs). One important advantage over finite element or finite difference methods for solving PDEs is dimension reduction: unknowns are distributed about the boundary instead of the entire domain. There are two projects involving integral equation methods and fluid dynamics:

Project 1: Vortex Motion on the Sphere
This project involves computing the motion of vortices on the earth's surface in the presence of multiple islands. This requires coupling the solution to an integral equation with a set of ordinary differential equations for the motion of the vortices. The work will focus on accurate time integration methods for this problem.

Project 2: Integral Equation Formulations in Fluid Dynamics
This project involves reformulating the Navier Stokes equations as integral equations. In addition to computing, this work will involve analysis.

Both of these projects will require basic familiarity with matlab.

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Joint: Adam Oberman and Steve Ruuth

Project: Applied math for movie special effects, video game design and image registrations (2 students)

Applications of variational methods and nonlinear partial differential equations to problems in image processing (image denoising, image registration) and surface and volumen deformations which are used for gaming and film special effects.

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Supervisor: D Muraki

Project: Computation of Fluid Models for Atmospheric Science

Undergraduates in the third and fourth year of their degree are invited to join a research group that investigates fluid mechanical models for atmospheric sciences. There are active projects that investigate a variety of atmospheric phenomena. One such project would involve using a simple computational model for fluid flows on a sphere, and compating the results with stratospheric weather data. Some background in a differential equations is essential and proficiency in a computational environment such as Matlab is preferable. Students taking MATH 462 in Spring 2012 will be well-prepared for this type of research.

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Supervisors: Tom Brown and Veselin Jungic

Title: Double arithmetic progressions

Abstract: This project is built around the following open problem: For a given positive number r greater than 1, is there a positive number w*(r,3) such that for any r-partition of the interval [1,w*(r,3)] there is a part A={x_1<x_2<...} that contains a 3-term arithmetic progression x_i, x_j, x_k with he property that the indices i, j, k also form an arithmetic progression? Variations of this problem and its relation with the problem of the avoidability of additive squares will also be considered. The student will also become familiar with van der Waerden’s Theorem and some other fundamental theorems in Ramsey theory.

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Supervisor: John Stockie and JF Williams

Project: Why don't honeybees freeze in winter?

When a new queen honeybee is born, the colony splits in two and one queen leads half the colony off to find a new home. Until the bees are able to find a suitable sheltered location, they first form a cluster that hangs from a tree limb in the open air. In winter, the bees would quickly perish without some way of keeping themselves warm. Our aim is to study the phenomenon of "thermoregulation" in which honeybee clusters generate heat by vibrating their flight muscles thereby keeping themselves, and the new queen in the centre of the cluster, from freezing to death. This project will apply techniques from applied mathematics such as dimensional analysis, modelling with differential equations, and numerical methods. So we are looking for a student who has taken the courses MACM 316 and MATH 310, or equivalent.

By the way, this project will also answer the equally compelling question: How do seemingly defenseless honeybees protect themselves from attacking teams of giant killer wasps?

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Supervisor: Nils Bruin

Project: Explorations in Arithmetic Geometry

Arithmetic geometry studies the interaction between geometry and number
theory. This leads to a particularly rich theory with many deep and
surprising results. It is also an area in which mathematical
experimentation has turned out to be of essential importance. Once one
assumes some deep standard results it is often possible to do meaningful
numerical experiments with relatively elementary means. The aim of this
project is to undertake such experimentations. The exact details will be
established in coordination with the student.