2009-2011 Mathematics Colloquia
Schedule for Fall 2011
Washington & Lee University, Nobel Symposium. Jacob Siehler: The 2011 Abel Prize
Time: 12:30 p.m., Wednesday, November 30
Place: Hillel Multi-purpose Room
Lunch will be paid by the Office of the Dean.
Abstract: The Norwegian Academy of Science and Letters has decided to award the Abel Prize for 2011 to John Milnor of the Institute for Mathematical Sciences, Stony Brook University, New York "for pioneering discoveries in topology, geometry and algebra.
A Visitor's Guide to Financial and Actuarial Mathematics
Jungmin Choi
Time: 4:40 p.m., Thursday, December 1st
Place Robinson 6
Refreshments at 4:15 pm
Abstract: Those who understand interest theory can be informed borrowers, making intelligent choices about mortgages and other loans, and they can also be wise investors. The students in this class learn now investment grows over time using mathematically precise methods. This course also helps prepare students for the actuarial exam, 2/FM.
In this "Visitor's Guide" talk, several annuity problems will be introduced including student loan payments and car loan payments. The last example in this talk is a practice exam problem from actuarial exam 2/FM, which uses put-call parity.
A Visitor's Guide to Number Theory, Math 365
Carrie Finch
Time: 4:40 pm, October 11
Place Robinson Hall, Room 6
Refreshments at 4;15 in Robinson 2
Abstract: Number theory is the elegant branch of pure mathematics devoted to the study of numbers, especially the integers. In this talk, we highlight some of the interesting problems and techniques that arise in elementary number theory. Don't let the name fool you -- this means number theory that does not rely on tools from other mathematical fields.
Mercer Consulting
Time: 4:40 pm, Monday, October 24
Place: Robinson Hall, Room 6
Students' Presentations
Time: 3:35 pm, Friday October 28
Place: Robinson Hall, Room 6
A Visitor's Guide to ODEs and PDEs
Paul Bourden
Time: 3:35 pm, Thursday, November 10
Place: Robinson Hall, Room 6
Schedule for Spring 2011
Honors Thesis Defense: Arithmetic Progressions in Permutations
Kyle Parsons, Washington & Lee University, Class of 2011
Time: 4:00 - 5:00pm, Monday, May 9
Place: Robinson Hall, Room 6
Abstract: Arithmetic progressions in permutations have been studied for over sixty years, often under other names. Our focus is on permutations with progressions of distance 1 and rise 1 or 2. We generalize some of the previous results by examining circular permutations and modular progressions. We also find an n-to-1 correspondence from regular permutations with modular progressions to circular permutations with regular progressions.
Underwater Rocket Science
Michele Theroux, Class of 2007
Time: 3:35 - 4:30, Thursday, May 12
Place: Robinson Hall, Room 6
Abstract: I will discuss life after graduation, how I became a torpedo analyst working as a contractor for the Navy and what torpedo analysis entails.
Honors Thesis Defense: Superdense Coding with Partially Entangled Quantum Particles
Lu Li, Washington & Lee University, Class of 2011
Time: 2:00-3:00 p.m., Friday, May 13
Place: Robinson Hall, Room 6
Schedule for Winter 2011
A Visitor's Guide to Upper Level Mathematics Courses
W&L math professors will present an overview of the ideas, problems, and theories that are discussed in upper-level math courses to give calculus students and others a glimpse of upper-level mathematics. These survey talks should be valuable and accessible to anyone with an interest in mathematics, having a calculus background.
A Visitor's Guide to Math 301: Fundamental Concepts
Paul Bourdon, Washington & Lee University
Time: 3:35 - 4:30pm, Thursday, January 20th
Place: Robinson Hall, Room 6
A Visitor's Guide to Math 353: Numerical Analysis
Jacob Siehler, Washington & Lee University
Time: 3:35 - 4:30pm, Wednesday, February 2nd
Place: Robinson Hall, Room 6
Pi Mu Epsilon
A Visitor's Guide to Math 321-322: Abstract Algebra
Wayne Dymacek, Washington & Lee University
Time: 3:35 - 4:30pm, Thursday, February 17th
Place: Robinson Hall, Room 6
A Visitor's Guide to Math 311-312: Real Analysis
Paul Humke, Washington & Lee University
Time: 3:35 - 4:30pm, Wednesday, March 9th
Place: Robinson Hall, Room 6
Finding Mathematics in Puzzles & Games
Adam Berliner, St. Olaf College
Time: 3:35 - 4:30pm, Thursday, March 24th
Place: Robinson Hall, Room 6
Abstract: For centuries, people have been fascinated and even sometimes preoccupied with puzzles and games. In this talk we'll learn some elementary graph theory. Using this along with a small amount of linear algebra and some mathematical savvy, we'll discuss how puzzles such as Magic Squares and Sudoku and games such as Othello can motivate some pretty interesting and deep mathematics.
A Visitor's Guide to Math 309-310: Probability & Statistics
Nathan Feldman, Washington & Lee University
Time: 3:35 - 4:30pm, Thursday, March 31st
Place: Robinson Hall, Room 6
Honors Thesis Defense: Hermitian Weighted Composition Operators on Weighted Hardy Spaces
Wenling Shang, Washington & Lee University, Class of 2011
Time: 3:35 - 4:30pm, Thursday, April 7
Place: Robinson Hall, Room 6
Schedule for Fall 2010
Careers in Actuarial Science
Presentation by Colin Bracis (‘03) and Agata Kasza ('10), representatives of Mercer, Inc.
Time: 4:40 p.m., Thursday, September 16th
Place: Robinson Hall, Room 6
Origami and Graph Theory: Birds, Balls, and multi-colored maps
Josie Ryan, Lander University
Time: 3:35-4:30p.m., Wednesday, September 22
Place: Robinson Hall, Room 6
Abstract: We will use origami, including the flapping crane and Thomas Hull's PHiZZ units, to demonstrate concepts from graph theory with applications to 2- and 3-colorings of maps. We will discuss the edge colorings of soccer balls and bucky balls and create a coloring of a dodecahedron. We will use Euler's theorem to explain our results. We will look at a proof by Kempe and Heawood (1879 and 1890) that states: If $G$ is a planar graph, then $\chi{G}\leq 5$ and quickly discuss the work by Koch, Appel, and Haken which lowered the number of require colors to four.
Math Majors Can Get Jobs Too!
Ericson Davis, Logistics Management Institute, W&L Class of 2003
Time: 4:40-5:35 p.m., Thursday, October 7
Place: Robinson Hall, Room 6
Title: Mathematical Models of Respiratory Diseases
Meagan Herald, Virginia Military Institute
Time: 3:35-4:30 p.m., Thursday, October 28
Place: Robinson Hall, Room 6
Abstract: A properly functioning immune system is required to maintain a healthy respiratory system. Dysfunctions in this system can cause bacterial colonization and chronic inflammation which in turn lead to damaged respiratory tissue, potential respiratory failure or even death. In order to manage respiratory inflammation and bacterial colonization, therapies need to focus on improving the function and activation levels of innate immune cells and immune secretions. Mathematical biology can be used to identify potential therapeutic targets, focusing experiments and describing the structures underlying complex biological systems.
We will explore two different models to understand the dynamics of bacterial infections in patients with cystic fibrosis. The first model consists of a system of nonlinear ordinary differential equations to describe interactions of the immune response. This model demonstrates, through bifurcation analysis, that nonaggressive bacteria are able to initiate chronic inflammation and suggests that therapies targeted towards restoring innate immune function will be vital to managing inflammatory respiratory diseases. The second model considers the interactions of a quorum sensing bacteria and the consequences of a slow moving mucociliary tract. This system of nonlinear partial differential equations allows us to determine what conditions promote biofilm formation and when the biofilm formations will occur.
Parents and Family Weekend Student Presentations
Time: 3:35-4:40 p.m., Friday, November 5
Place: Robinson Hall, Room 6
It's Easy as 1-2-3 or 2-1-3 or 3-2-1 or...
Kyle Parsons ('11)
Superdense coding with partially entangled quantum particles
Lu Li ('11) and Wendy Shang ('11)
Abstract: Suppose that each of two parties "Alice and Bob" possesses one particle of a two-particle entangled quantum system and that Alice wishes to send a message to Bob via her particle. Roughly speaking, the more entangled their shared system, the greater the possible efficiency of the communication between Alice and Bob using the system. The precise relationship between degree of entanglement and communication efficiency is not understood. We will discuss this relationship.
Lucas Riesel and Lucas Sierpinski numbers
Olaolu Fasoranti ('12)
Abstract: In 1960, W. Sierpinski discovered that k = 1511380746462593381 has the property that k · 2 n + 1 is composite for any positive integer n. Because of his discovery, we call any positive integer k such that k · 2 n + 1 is always composite a Sierpinski number. In 2009, F. Luca and J. Mejıa discovered that there are infinitely many numbers in the Fibonacci sequence that are also Sierpinski numbers. They also found that there are infinitely many numbers in the Fibonacci sequence that are also Riesel numbers - a positive integer k such that k · 2 n - 1 is always composite for any positive integer n. In this talk, we show that there exists infinitely many Lucas-Riesel and Lucas-Fibonacci numbers for the Lucas sequence which is a generalized Fibonacci sequence which begins with 2 and 1.
Schedule for Winter 2010
Diophantine Equations Involving Factorials
Dan Baczkowsi, Washington and Lee
Time: 3:30 p.m., Wednesday March 3
Place: Robinson Hall, Room 6
Abstract: By "Diophantine equation" we merely mean an equation in which we are only concerned with positive integer solutions. Hence, the goal is to completely solve a particular Diophantine equation or to determine if the equation has finitely many solutions. Diophantine equations involving factorials have predominantly been studied utilizing techniques from the pulchritudinous subject of number theory. Among them are some outstanding problems aging over 130 years. The focus of the presentation will be on the improvements of problems investigated by Florian Luca. Those improvements are joint work with Florian Luca, Michael Filaseta, and Ognian Trifonov.
Dense Coding with Partially Entangled Quantum Particles
Paul Bourdon, Washington and Lee
Time: 3:30 p.m., Wednesday March 17
Place: Robinson Hall, Room 6
Abstract: By sliding a coin across a dining table to your friend "Bob", you can convey one of two messages: "heads" (which might mean "pass the salt") or "tails" (which might mean "pass the pepper"). However, if you and Bob share two fully entangled "quantum coins" (one in Bob's possession and one in yours), you can send one of four different messages with your quantum coin. When Bob looks at your quantum coin he will see either heads (H) or tails (T), but you can prepare your coin in such a way that when he looks at both your coin and his, he will see exactly that sequence in {HH, HT, TH, TT} that you wish him to see, and thus receive one of four messages from your two-sided quantum coin. This is a simple example of the magic of dense coding, in which the quantum coins might be photons (with, e.g., heads = vertically polarized; tails = horizontally polarized). In general, dense coding involves two parties, customarily called Alice and Bob, with each assumed to possess one of a pair of entangled d-dimensional quantum particles known as qudits. If the pair of qudits that Alice and Bob share is fully entangled, then in theory Alice can convey one of d-squared messages to Bob via her qudit. These messages are prepared/encoded by Alice by applying to her qudit a physical operation modeled by a d x d unitary matrix; moreover, in order that the messages encoded by Alice never be misinterpreted by Bob, the messages must correspond to orthogonal vectors in the state space of the two-qudit system that Alice and Bob share. The mathematics of this situation will be the focus of the talk, with the principal research-level issue being: how is the number of distinct messages that Alice may encode related to the degree of entanglement of the two-qudit system she and Bob use as the basis for their communication?
When Does Appending the Same Digit Repeatedly on the Right of a Positive Integer Generate a Sequence of Composite Integers?
Lenny Jones, Shippensburg University
Time: 4:30 p.m., Thursday March 25*
Place: Robinson Hall, Room 6
Abstract: Let d=1, 3, 7 or 9, and let k be a positive integer relatively prime to d. A sequence s_1, s_2, ... of positive integers is constructed in the following way: Suppose that k = a_1a_2...a_t is the decimal digit representation of k, reading from left to right. Form s_n by appending the digit d n times to the right side of the decimal digit representation for k. For example, if k=135, then the sequence is 135d, 135dd, 135ddd, 135dddd, .... For each d we address the following questions:
1. Does there exist a positive integer k such that s_n is composite for all integers greater than or equal to 1?
2. If the answer to question 1. is yes, then can we find a smallest such positive integer k?
Calculus on Time Scales
Lea Lanz, Virginia Military Institute
Time: 3:30 p.m., Wednesday April 7*
Control Theory Analysis of a Structural Acoustic System
P. Jameson Graber, University of Virginia
Time: 3:30 p.m., Wednesday May 5*
Abstract: Many real world engineering problems, for instance the problem of stabilizing an acoustic chamber, can be modeled mathematically and studied from the point of view of mathematical control theory. The basic philosophy of control theory can be summarized in a three step process: (1) model the physical system using a system of partial differential equations; (2) study the mathematical properties of the system of equations; and (3) alter the model to achieve desired results. In this presentation, I will use the structural acoustic model as an example to illustrate the basic philosophy of control theory. Of the three basic steps of control theory outlined above, step (2) will receive the most attention. I will explain the concept of a well-posed dynamical system and attempt to describe in general terms the tools in analysis used to prove that a dynamical system is well-posed. Additionally I will introduce topics relevant to control, including asymptotic and uniform decay rates of solutions of a dynamical system. This will lead to a discussion of how adding controls can alter the behavior of a dynamical system to obtain optimal results. I will conclude the presentation by describing how controls can be added to optimize stability in the structural acoustic model, and why this is important in real-world applications.
*Refreshments at 3:15 p.m. in Robinson Hall 2
Schedule for Fall 2009
When you can't be with the one you love, take a slow bus to Budapest: A combinatorial look at arithmetic progressions in permutations.
Wayne M. Dymacek, W&L Mathematics Department
Wayne M. Dymacek, W&L Mathematics Department
Time: 3:30pm, Wednesday, September 23*
Place: Robinson Hall, Room 6
Careers in Actuarial Science
Presentation by Mercer
Time: 4:40, Wednesday, October 7*
Place: Robinson Hall, Room 6
Spectral Pictures, Special Generators, and Infinite Checkerboards
Nathan Feldman, W&L Mathematics Department
Time: 3:30pm, Wednesday, October 21*
Place: Robinson Hall, Room 6
W&L Student Presentations
Sarah Merritt & Cliff Gaddy, Neville Fogarty, and Kelsey Wright
Time: 4:40pm, Friday, October 30*
Place: Robinson Hall, Room 6
Mathematics and Air Traffic Flow Management
Christy Spofford Bittle
Time: 3:30pm, Wednesday, November 4*
Place: Robinson Hall, Room 6
Abstract: Demand in the National Airspace System is expected to double or triple by the year 2025. During this time, it is unlikely that airspace infrastructure, such as new runways and airports, will alone be sufficient to meet the increased demand. Current avenues of research look to not only alleviate current congestion problems in the airspace but also to anticipate and address new problems that will arise with this increased demand. I will discuss some of these avenues of research, as well as how my background in mathematics relates to the research being done.
Cyclotomic polynomials, their gcd, and their resultants
Greg Dresden, W&L Mathematics Department
Time: 3:30pm, Wednesday, November 11*
Place: Robinson Hall, Room 6
Abstract: Recall that the cyclotomic polynomials, which begin x - 1, x + 1, x^2 + x + 1, x^2 + 1, ... , are the irreducible factors of x^n - 1. We show that most of the time we can give a linear combination of two cyclotomic polynomials that is equal to 1, but sometimes we can only get p, a prime. We show how this lemma is related to the resultant.
*Refreshments 20 minutes before the talk begins in Robinson Hall, Room 2
Schedule for Spring 2009
Solving Graph Isomorphisms via Hyperdimensional Noise
Simon D. Levy, W&L Department of Computer Science and Program in Neuroscience
Time: 3:30pm, Thursday, April 30
Place: Robinson Hall, Room 6
But I Don't Want to be an Actuary!
Meagan Clement, W&L Class of '02
Time: 4:40pm, Thursday, April 23*
Place: Robinson Hall, Room 6
Dr. Clement earned a Ph.D. in biostatistics from UNC-Chapel Hill in 2008 and currently works for Rho Inc., a contract research organization providing support to the pharmaceutical/biotech industry.
*Refreshments at 4:20 in Robinson Hall 2
Schedule for Winter 2009
On Sums of Powers of Primes
Florian Luca, Universidad Nacional Autónoma, De México
Time: 4:40, Tuesday, March 24*
Place: Robinson Hall, Room 6
*Refreshments at 4:20pm in Robinson Hall 2
Pi Mu Epsilon Speaker
It was the quickest of times, it was the sameness of times
Steve Abbott, Middlebury College
Time: 4:30, Tuesday, March 17*
Place: Robinson Hall, Room 6
*Refreshments at 4:00 p.m. in Robinson Hall 2
An Introduction to the Mystery of Fractals
Zoltán Buczolich, Eötvös Loránd University, Budapest, Hungary
Time: 4:40pm Thursday, February 26*
Place: Robinson Hall, Room 6
*Refreshments at 4:20 p.m. in Robinson Hall 2