Seminars and Colloquia by Series

Cost Theory and Geometric Dualities

Series
Analysis Seminar
Time
Wednesday, April 2, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location
Skiles 005
Speaker
Shay SadovskyCourant Institute

In the classical theory of optimal transport, Legendre duality arises naturally, as seen for example in Kantorovich’s duality theorem. Extending this idea to a general cost function naturally leads to a broader notion of functional cost-duality and the associated class of c-functions.

Similarly, in the setting of sets, taking polars provides an analogous notion of duality, mapping to the class of convex sets. In this talk, I will introduce cost dualities for sets and show that they correspond precisely to all order-reversing involutions on sets. Finally, I will explore the connections between c-duality and various geometric and functional inequalities.

Generalized Olson-Zalik Conjecture

Series
Analysis Seminar
Time
Wednesday, April 2, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location
Skiles 005
Speaker
Pu-Ting YuUniversity of Oregon

In 1992, Olson and Zalik conjectured that no system of translates can be a Schauder basis for L^2(R). This conjecture remains open as of the time of writing. Although some partial results regarding Olson-Zalik conjecture have been proved to be true, a characterization of subspaces of L^2(R) that do not admit a Schauder basis, or an unconditional basis is still unknown. 

In this talk, we will begin with a brief introduction to Olson-Zalik conjecture including its recent development. Then we will show that a family of modulation spaces do not admit unconditional bases formed by a system of translates. This observation led us to the following generalized Olson-Zalik conjecture ``Assume X is a separable Banach space that is continuously embedded into L^2(R). Then X does not admit a Schauder basis of translates if it is closed under Fourier transform". Finally, we close this talk by showing that if a closed subspace of L^2(R) is closed under Fourier transform, then it does not admit a Schauder basis of certain translates.

VC dimension and point configurations in fractals

Series
Analysis Seminar
Time
Wednesday, March 12, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location
Skiles 005
Speaker
Alexander McDonaldKennesaw State

An important class of problems at the intersection of harmonic analysis and geometric measure theory asks how large the Hausdorff dimension of a set must be to ensure that it contains certain types of geometric point configurations. We apply these tools to study configurations associated to the problem of bounding the VC-dimension of a naturally arising class of indicator functions on fractal sets.

Cylindrical Martingale-Valued Measures, Stochastic Integration and SPDEs

Series
Analysis Seminar
Time
Wednesday, February 19, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location
Skiles 005
Speaker
Dario MenaUniversity of Costa Rica

We develop a theory of Hilbert-space valued stochastic integration with respect to cylindrical martingale-valued measures. As part of our construction, we expand the concept of quadratic variation, to the case of cylindrical martingale-valued measures that are allowed to have discontinuous paths; this is carried out within the context of separable Banach spaces. Our theory of stochastic integration is applied to address the existence and uniqueness of solutions to stochastic partial differential equations in Hilbert spaces. 

Fractionally modulated discrete Carleson's Theorem and pointwise Ergodic Theorems along certain curves

Series
Analysis Seminar
Time
Wednesday, February 12, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location
Skiles 005
Speaker
Anastasios FragkosGeorgia Institute of Technology

For \( c\in(1,2) \) we consider the following operators
\[
\mathcal{C}_{c}f(x) \colon = \sup_{\lambda \in [-1/2,1/2)}
\bigg| \sum_{n \neq 0} f(x-n) \frac{e^{2\pi i\lambda \lfloor |n|^{c} \rfloor}}{n} \bigg|\text{,}
\]
\[
\mathcal{C}^{\mathsf{sgn}}_{c}f(x) \colon = \sup_{\lambda \in [-1/2,1/2)}
\bigg| \sum_{n \neq 0} f(x-n) \frac{e^{2\pi i\lambda \mathsf{sign}(n) \lfloor |n|^{c} \rfloor}}{n} \bigg| \text{,}
\]
and prove that both extend boundedly on \( \ell^p(\mathbb{Z}) \), \( p\in(1,\infty) \). 

The second main result is establishing almost everywhere pointwise convergence for the following ergodic averages
\[
A_Nf(x)\colon =\frac{1}{N}\sum_{n=1}^N f(T^n S^{\lfloor n^c\rfloor} x) \text{,}
\]
where $T,S\colon X\to X$ are commuting measure-preserving transformations on a  $\sigma$-finite measure space $(X,\mu)$, and $f\in L_{\mu}^p(X), p\in(1,\infty)$. 

The point of departure for both proofs is the study of exponential sums with phases  $\xi_2 \lfloor |n^c|\rfloor+ \xi_1n$ through the use of a simple variant of the circle method.

This talk is based on joint work with Leonidas Daskalakis.
 

Characterizing Submodules in $H^2(\mathbb{D}^2)$ Using the Core Function

Series
Analysis Seminar
Time
Wednesday, January 29, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location
Skiles 005
Speaker
Victor BaileyUniversity of Oklahoma

It is well known that  $H^2(\mathbb{D}^2)$ is a RKHS with the reproducing kernel $K( \lambda, z) = \frac{1}{(1-\overline{\lambda_1}z_1)(1 - \overline{\lambda_2}z_2)}$ and that for any submodule $M \subseteq H^2(\mathbb{D}^2)$ its reproducing kernel is $K^M( \lambda, z) = P_M K( \lambda, z)$ where $P_M$ is the orthogonal projection onto $M$. Associated with any submodule $M$ are the core function $G^M( \lambda, z) = \frac{K^M( \lambda, z)}{K( \lambda, z)}$ and the core operator $C_M$, an integral transform on $H^2(\mathbb{D}^2)$ with kernel function $G^M$. The utility of these constructions for better understanding the structure of a given submodule is evident from the various works in the past 20 years. In this talk, we will discuss the relationship between the rank, codimension, etc. of a given submodule and the properties of its core function and core operator. In particular, we will discuss the longstanding open question regarding whether we can characterize all submodules whose core function is bounded. This is a joint project with Rongwei Yang. 

Pointwise ergodic theorems along fractional powers of primes. (Note the special location)

Series
Analysis Seminar
Time
Wednesday, January 15, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location
Van Leer C456
Speaker
Leonidas DaskalakisWroclaw University

 We establish pointwise convergence for nonconventional ergodic averages taken along $\lfloor p^c\rfloor$, where $p$ is a prime number and $c\in(1,4/3)$ on $L^r$, $r\in(1,\infty)$. In fact, we consider averages along more general sequences $\lfloor h(p)\rfloor$, where $h$ belongs in a wide class of functions, the so-called $c$-regularly varying functions. A key ingredient of our approach are certain exponential sum estimates, which we also use for establishing a Waring-type result. Assuming that the Riemann zeta function has any zero-free strip upgrades our exponential sum estimates to polynomially saving ones and this makes a conditional result regarding the behavior of our ergodic averages on $L^1$ to not seem entirely out of reach. The talk is based on joint work with Erik Bahnson, Abbas Dohadwala and Ish Shah.
 

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