Seminars and Colloquia by Series

Series

Bridging Scientific Computing and Machine Learning through Stochastic and Data-Driven Solvers

Series: Applied and Computational Mathematics Seminar
Time: Monday, November 10, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location: Skiles 005 and https://gatech.zoom.us/j/94954654170
Speaker: Tianshi Xu – Emory University – tianshi.xu@emory.edu

Classical solvers for large-scale scientific and data-driven problems often face limitations when uncertainty, multiscale effects, or ill-conditioning become dominant. In this talk, I will present hybrid algorithmic frameworks that unify ideas from numerical analysis, stochastic computation, and machine learning to address these challenges. In the first part, I will introduce Preconditioned Truncated Single-Sample (PTSS) estimators, a new class of stochastic Krylov methods that integrate preconditioning with truncated Lanczos iterations. PTSS provides unbiased, low-variance estimators for linear system solutions, log-determinants, and their derivatives, enabling scalable algorithms for inference and optimization. In the second part, I will discuss a data-driven approach to constructing approximate inverse preconditioners for partial differential equations (PDEs). By learning the Green’s function of the underlying operator through neural representations, this framework captures multiscale behavior and preserves essential spectral structure. The resulting solvers achieve near-linear complexity in both setup and application. Together, these developments illustrate how stochastic and learning-based mechanisms can be embedded into classical numerical frameworks to create adaptive and efficient computational methods for complex systems.

An Excision Theorem in Heegaard Floer Theory

Series: Geometry Topology Seminar
Time: Monday, November 10, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location: Skiles 006
Speaker: Neda Bagherifard – Georgia Tech

In this talk, I will describe an excision construction for 3-manifolds and explain how (twisted) Heegaard Floer theory can be used to obstruct 3-manifolds from being related via such constructions. I will also discuss how the excision formula can be applied to compute twisted Heegaard Floer homology groups for specific 3-manifolds obtained by performing surgeries on certain links, including some 2-bridge links.

Iterators in Numerical Algebraic Geometry

Series: Algebra Seminar
Time: Monday, November 10, 2025 - 13:00 for 1 hour (actually 50 minutes)
Location: Skiles 005
Speaker: Taylor Brysiewicz – University of Western Ontario

Please Note: There will be a pre-seminar 10:55-11:15 in Skiles 005.

At its core, numerical algebraic geometry is the business of solving zero-dimensional polynomial systems over the complex numbers. Thanks to incredibly fast state-of-the-art software implementations, the bottleneck in these algorithms has shifted from computation time to memory usage.

To address this, recent work has introduced iterator datatypes for solution sets. An iterator represents a list by storing a single element and providing a mechanism to obtain the next one, thereby reducing memory overhead.

In this talk, we present our design of 'homotopy iterators' and 'monodromy coordinates', two iterator datatypes based on the most widely used numerical methods for solving polynomial systems. We highlight the substantial benefits of this low-memory perspective through several iterator-friendly adaptations of existing algorithms, including parameter space searches, data compression, and certification.

This talk features joint work with subsets of Paul Breiding, Hannah Friedman, and David K. Johnson.

Geodesics and approximate geodesics in critical 2D first-passage percolation

Series: Stochastics Seminar
Time: Thursday, November 6, 2025 - 15:30 for 1 hour (actually 50 minutes)
Location: Skiles 006
Speaker: Erik Bates – North Carolina State University – ebates@ncsu.edu

First-passage percolation on the square lattice is a random growth model in which each edge of Z^2 is assigned an i.i.d. nonnegative weight. The passage time between two points is the smallest total weight of a nearest-neighbor path connecting them, and a path achieving this minimum is called a geodesic. Typically, the number of edges in a geodesic is comparable to the Euclidean distance between its endpoints. However, when the edge-weights take the value 0 with probability exactly 1/2, a strikingly different behavior occurs: geodesics travel primarily on critical clusters of zero-weight edges, whose internal graph distance scales superlinearly with Euclidean distance. Determining the precise degree of this superlinear scaling is a challenging and ongoing endeavor. I will discuss recent progress on this front (joint with David Harper, Xiao Shen, and Evan Sorensen), along with complementary results on a dual problem, where we restrict path lengths and analyze passage times (joint with Jack Hanson and Daniel Slonim).

Computer Algebra club/seminar

Series: Additional Talks and Lectures
Time: Thursday, November 6, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location: Skiles 006
Speaker: Griffin Edwards – Georgia Tech

We will start with a presentation by Griffin Edwards and continue with a free discussion.

On two problems in scientific machine learning: learning interaction laws in particle systems, and digital twins in cardiac electrophysiology

Series: School of Mathematics Colloquium
Time: Thursday, November 6, 2025 - 11:00 for 1 hour (actually 50 minutes)
Location: Skiles 005
Speaker: Mauro Maggioni – Johns Hopkins University – mauromaggionijhu@icloud.com

I will discuss recent results in two research directions at the intersection of scientific machine learning and modeling of dynamical systems.

First, we consider systems of interacting agents or particles, which are commonly used in models throughout the sciences, and can exhibit complex, emergent large-scale dynamics, even when driven by simple interaction laws. We consider the following inference problem: given only observations of trajectories of the agents in the system, can we learn the unknown laws of interactions? We cast this as an inverse problem, discuss when this problem is well-posed, construct estimators for the interaction kernels with provably good statistical and computational properties, even in the nonparametric estimation regime when only minimal information is provided about the form of such interaction laws. We also demonstrate numerically that the estimated systems can accurately reproduce the emergent behaviors of the original systems, even when the observations are so short that no emergent behavior was witnessed in the training data. We also discuss the case where the agents are on an unknown network, and we need to estimate both the interaction kernel and the network.

In the second part of the talk, I will discuss recent applications of deep learning in the context of digital twins in cardiology, and in particular the use of operator learning architectures for predicting solutions of parametric PDEs, or functionals thereof, on a family of diffeomorphic domains — the patient-specific hearts -- which we apply to the prediction of medically relevant electrophysiological features of heart digital twins.

Variable coefficient local smoothing and a projection problem in the Heisenberg group

Series: Analysis Seminar
Time: Wednesday, November 5, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location: Skiles 005
Speaker: Terence Harris – University of Wisconsin-Madison – terry.harris@wisc.edu

The Heisenberg projection problem asks whether there is an analogue of the Marstrand projection theorem in the first Heisenberg group, namely whether Hausdorff dimension of sets generically decreases under projection, for a natural family of projections arising from the group structure. This problem is still open, but I will discuss a recent improvement to the known bound obtained through a variable coefficient local smoothing inequality.

Rather than going through the proof in detail, I will spend most of the talk introducing the problem and explaining the connection to averaging operators over curves, and explaining why these operators are Fourier integral operators satisfying Sogge's cinematic curvature condition. This condition was originally introduced by Sogge to generalise Bourgain's circular maximal theorem, but it turns out to have useful applications to projection theory.

Branched covers over chi-slice links bounding rational balls

Series: Geometry Topology Student Seminar
Time: Wednesday, November 5, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location: Skiles 006
Speaker: Kalev Martinson – Georgia Tech

Two prominent questions in low dimensional topology are: which knots are slice, and which $\mathbb{Q}$-homology $S^3$'s bound $\mathbb{Q}$-homology $B^4$'s? These questions are connected by a theorem that states if a knot $K$ in $S^3$ is slice, then the 2-fold branch cover of $S^3$ over $K$ bounds a $\mathbb{Q}$-homology $B^4$. In this talk we introduce a generalization of $\chi$-sliceness of links to the rational homology context, generalize the earlier theorem to state that for a rationally $\chi$-slice link $L$, for all sufficiently large primes $p$, the $p$-fold cyclic branch cover of $S^3$ over $L$ bounds a $\mathbb{Q}$-homology $B^4$, and examine a connection to a number-theoretic obstruction on the Alexander polynomial.

Nearly optimal and tractable estimation of recurrent sequences

Series: Research Horizons Seminar
Time: Wednesday, November 5, 2025 - 12:30 for 1 hour (actually 50 minutes)
Location: Skiles 005
Speaker: Dmitrii Ostrovskii – Georgia Tech – ostrov@gatech.edu

How hard is it to estimate a sequence of length N, satisfying some *unknown* linear recurrence relation of order S and observed in additive Gaussian noise? The class of all such sequences is extremely rich: it is formed by arbitrary (complex) exponential polynomials with total degree S. This includes the case of stationary sequences, a.k.a. harmonic oscillations, a.k.a. sequences with discrete Fourier spectra supported on S *arbitrary* frequencies. Strikingly, it turns out that one can estimate such sequences with almost the same statistical error as if the recurrence relation was known (and a simple least-squares estimator could be used). In particular, stationary sequences can be estimated with mean-squared error of order O(S/N) up to a polylogarithmic factor, without any assumption of spectral separation—despite what one might learn in a high-dimensional statistics class. Moreover, these methods are computationally tractable.

In this talk, I will highlight some mathematics underlying this result, putting emphasis on analytical, rather than statistical, side of things. In particular, I will show how to invert a polynomial while ensuring that the result is a polynomial—rather than a reciprocal of a polynomial—and what this has to do with reproducing kernels. Then, I will pitch some accessible open problems in this area.

New perspectives on learning networks from dynamics

Series: Stochastics Seminar
Time: Tuesday, November 4, 2025 - 15:30 for 1 hour (actually 50 minutes)
Location: Skiles 006
Speaker: Ani Sridhar – New Jersey Institute of Technology – anirudh.sridhar@njit.edu

Suppose that a continuous-time, stochastic diffusion (i.e., the Susceptible-Infected process) spreads on an unknown graph. We only observe the time at which the diffusion reaches each vertex, i.e., the set of infection times. What can be learned about the unknown graph from the infection times? While there is far too little information to learn individual edges in the graph, we show that certain high-level properties -- such as the number of vertices of sufficiently high degree, or super-spreaders -- can surprisingly be determined with certainty. To achieve this goal, we develop a suite of algorithms that can efficiently detect vertices of degree asymptotically greater than sqrt(n) from infection times, for a natural and general class of graphs with n vertices. To complement these results, we show that our algorithms are information-theoretically optimal: there exist graphs for which it is impossible to tell whether vertices of degree larger than n^{1/2 - \epsilon} exist from vertices' infection times, for any \epsilon > 0. Finally, we discuss the broader implications of our ideas for change-point detection in non-stationary point processes. This talk is based on joint work with Anna Brandenberger (MIT) and Elchanan Mossel (MIT).

Georgia Institute of Technology College of Sciences

Search form