Events

Title: Biased cliques

Abstract: A biased clique is a collection of cycles in a complete graph G so that no theta of G contains exactly two cycles in the collection. They have interesting connections to both matroids and groups; I will give a survey of some results on these objects.

Title: Vertex models for the product of a Schur and Demazure polynomial

There will be a pre-seminar presenting relevant background at the beginning graduate level starting at 1pm.

Abstract: Demazure atoms and characters are polynomials that each form a Z-basis for polynomials in n variables. The product of a Schur polynomial with a Demazure atom (resp. character) expands into a linear combination of Demazure atoms (resp. characters) with positive integer structure coefficients. There are known combinatorial rules that compute these coefficients using "skyline tableaux" given by Haglund, Luoto, Mason and Willigenburg. I have found alternative rules using the theory of integrable vertex models, inspired by a technique introduced by Zinn-Justin.

Title: Online Edge Coloring with Tree Recurrences

Abstract: We will talk about online edge coloring in the edge arrival model. The vertex set V is known, and each edge arrives one by one, where it has to be colored irrevocably immediately. I will present the results from Kulkarni, Liu, Sah, Sawhney and Tarnawski [STOC 2022] which gives an algorithm that colors the graph with (e/e-1 + o(1))\delta colors.

Title: Subconstituents of Drackns 

Abstract: For a distance-regular graph X and an arbitrary vertex v, we often find interesting structure in the subgraph of X induced on vertices at distance 2 from v.

For example:

Any strongly-regular graph with parameters (n,k,a,k/2) can be found at distance 2 from a vertex in a distance-regular graph of diameter 3.

Certain distance-regular graphs of diameter 3 can be found at distance 2 from a vertex in a Moore graph of girth 5.

These (and more) examples are known as second-subconstituents, and they can be studied using the Terwilliger (or subconstituent) algebra of X. I will discuss this theory in the case that X is a distance-regular antipodal cover of a complete graph (drackn). This setting generalizes the first example and includes the second.

I will describe some general techniques for studying the Terwilliger algebras of drackns and then restrict to drackns without triangles. In this setting I will explain how to compute the spectrum of the second-subconstituent of any triangle-free drackn, except possibly the second-subconstituent OF a second-subconstituent of a Moore graph of valency 57.

Title: Odd cycle transversal in P5-free graphs

Abstract: Odd cycle transversal is a fun computational problem, somewhere between colouring and independent set: we are (equivalently) looking for a bipartite induced subgraph of maximum weight. As one might expect, this is NP-hard; I will tell you how to solve this problem in polynomial time in P5-free graphs (and more). Joint work with Cece Henderson, Evelyne Smith-Roberge, and Rebecca Whitman.

Note: I am COVID-cautious and will bring masks for those willing to wear them. 

Title: More Martin and c2 details.

There will be a pre-seminar presenting relevant background at the beginning graduate level starting at 1pm.  Please also come to the pre-seminar to discuss what sorts of snacks and refreshments we might want going forward.

Abstract:  I'm going to tell you more of the details behind my Martin polynomial work last year with Erik Panzer which led to the proof of the c2 completion conjecture. I will actually describe the key bijection that proves it all, say some things about the permanent invariant, and cover other details that there hadn't been time for in the colloquium level presentation of the result.

Title: A O(log log (rank) ) - competitive algorithm for the matroid secretary problem

Abstract: In the Matroid Secretary problem the weighted elements of a matroid arrive one by one in a uniformly random order where an online algorithm observes the value of the element and must make an irrevocable decision of whether or not to include the element in its solution before the arrival of the next element. The goal is to maximize the total value of the chosen elements under the condition that they must constitute an independent set. Other than knowing the cardinality of the ground set and having access to an independence oracle, the algorithm has no further information about the matroid.

Title: The limits of the inertia bound

Abstract: Spectral graph theory provides us with a wide array of surprising results which relate graph-theoretic parameters to linear-algebraic parameters of associated matrices. Among the most well-known and useful of these is Hoffman’s ratio bound, which gives an upper bound on the independence number of a graph in terms of its eigenvalues.

Title: Intersections of graphs and χ-boundedness: Interval graphs, chordal graphs, and χ-guarding graph classes

Abstract: Following A. Gyárfás (1987), we say that a hereditary class of graphs is χ-bounded if there exists a function which provides an upper bound for the chromatic number of each graph of the class in terms of the graph's clique number. In this terminology, E. Asplund and B.Grünbaum (1960),  motivated by a question of A. Bielecski (1948), proved that the class of intersection graphs of axis parallel rectangles is χ-bounded, and J. P. Burling, in his Ph.D. thesis (1965), proved that the class of intersection graphs of axis parallel boxes in R^3 is not χ-bounded.

Title: Real matroid Schubert varieties, zonotopes, and virtual Weyl groups

There will be a pre-seminar presenting relevant background at the beginning graduate level starting at 1pm.

Abstract: Every linear representation of a matroid determines a matroid Schubert variety whose geometry encodes combinatorics of the matroid. When the representation is over the real numbers, we show that the topology of these varieties is completely determined by the combinatorics of zonotopes. As an application, we compute the fundamental groups. When the real matroid Schubert variety comes from a Coxeter arrangement, we show that the equivariant fundamental group is a “virtual” analogue of the corresponding Weyl group.