Organizing Committee
Abstract

The program will explore different perspectives on uncertainty quantification, efficient simulation, and the analysis of complex stochastic systems. The topics covered will include exciting recent developments on efficient methods for approximating quasi-stationary distributions, simulation of equilibrium distributions, information divergences in sensitivity analysis of rare events, large deviations methods for efficient importance sampling, accelerated Monte Carlo via nonlinear PDE, and complex probabilistic models including reflected diffusions and high-dimensional dynamics arising in chemistry and physics.

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Confirmed Speakers & Participants

Talks will be presented virtually or in-person as indicated in the schedule below.

  • Speaker
  • Poster Presenter
  • Attendee
  • Virtual Attendee
  • Rami Atar
    Technion
  • Jeremiah Birrell
    Texas State University
  • Jose Blanchet
    Stanford
  • Vivek Borkar
    IIT Bombay, India
  • Wlodzimierz Bryc
    University of Cincinnati
  • Amarjit Budhiraja
    University of North Carolina at Chapel Hill
  • Benjamin Budway
    Princeton
  • Vladislav Bukshtynov
    University of Colorado Boulder
  • Fei Cao
    University of Massachusetts Amherst
  • Sandra Cerrai
    University of Maryland
  • Djalil Chafai
    Universite Paris-Dauphine
  • Daniel Chen
    Brown Univesity
  • Ziyu Chen
    University of Massachusetts Amherst
  • Juniper Cocomello
    Brown University
  • Cristina Costantini
    University of Chieti-Pescara
  • Constantine Dafermos
    Brown University
  • Michel Davydov
    Brown University
  • Paul Dupuis
    Brown University
  • Markus Fischer
    University of Padua
  • Thejani Gamage
    University of Massachusetts Amherst
  • Arnab Ganguly
    Louisiana State University
  • Ankan Ganguly
    Boston University
  • Nikos Georgoudios
    Boston University
  • Hyemin Gu
    University of Massachusetts Amherst
  • Binan Gu
    Worcester Polytechnic Institute
  • Yanqiu Guo
    N/A
  • Kevin Hu
    Brown University
  • Dane Johnson
    Elon University
  • Markos Katsoulakis
    University of Massachusetts Amherst
  • Johannes Krotz
    University of Notre Dame
  • Kevin Leder
    University of Minnesota
  • David Lipshutz
    Flatiron Institute
  • Jian-Guo Liu
    Duke University
  • Wenjian Liu
    City University of New York
  • Mengjie Liu
    Brown University
  • Sicheng Liu
    Brown University
  • Daniel McBride
    University of Tennessee, Knoxville
  • Siddharth Mitra
    Yale University
  • Stanley Nicholson
    Brown University
  • Fnu Nisha
    CLEMSON UNIVERSITY
  • Pierre Nyquist
    Chalmers University of Techology
  • Tao Pang
    North Carolina State University
  • Petr Plechac
    University of Delaware
  • Amber Puha
    CSU San Marcos
  • Kavita Ramanan
    Brown University
  • Luc Rey-Bellet
    UMass Amherst
  • Mickey Salins
    Boston University
  • Jiayuan Sheng
    Columbia University
  • Michael Snarski
    D. E. Shaw Research
  • Konstantinos Spiliopoulos
    Boston University
  • Mark Squillante
    IBM Research
  • Nathaniel Whitaker
    University of Massachusetts Amherst
  • Ruth Williams
    University of California, San Diego
  • Ruoyu Wu
    Iowa State University
  • Chen Yao
    Boston University
  • Yukun Yue
    University of Wisconsin, Madison
  • Benjamin Zhang
    Brown University
  • Yaochen Zhu
    Brown University

Workshop Schedule

Friday, September 13, 2024
  • 8:30 - 8:50 am EDT
    Check In
    11th Floor Collaborative Space
  • 8:50 - 9:00 am EDT
    Welcome
    11th Floor Lecture Hall
    • Session Chair
    • Brendan Hassett, ICERM/Brown University
  • 9:00 - 9:45 am EDT
    Paul Dupuis's Contributions to Large Deviations, Stochastic Control, and Numerical Methods
    11th Floor Lecture Hall
    • Speaker
    • Amarjit Budhiraja, University of North Carolina at Chapel Hill
    • Session Chair
    • Petr Plechac, University of Delaware
    Abstract
    In this talk I will present some highlights of Paul Dupuis' contributions to the areas of large deviations, stochastic control, and numerical methods.
  • 10:00 - 10:30 am EDT
    Coffee Break
    11th Floor Collaborative Space
  • 10:30 - 11:15 am EDT
    Large Deviations for Stochastic Approximations
    11th Floor Lecture Hall
    • Speaker
    • Pierre Nyquist, Chalmers University of Techology
    • Session Chair
    • Petr Plechac, University of Delaware
    Abstract
    The theory of stochastic approximations form the theoretical foundation for studying convergence properties of many popular recursive learning algorithms in statistics, machine learning and statistical physics. Large deviations for stochastic approximations provide asymptotic estimates of the probability that the learning algorithm deviates from its expected path, given by a limit ODE, and the large deviation rate function gives insights to the most likely way that such deviations occur. In this paper, the weak convergence approach to large deviations is developed for general stochastic approximations with state-dependent Markovian noise and decreasing step size. The results generalize previous results on large deviations for stochastic approximations and identifies the appropriate scaling sequence. A new representation of the rate function is given, where the rate function is expressed as an action functional involving the family of Markov transition kernels. Learning algorithms that satisfy the assumptions of the large deviation principle include stochastic gradient descent, persistent contrastive divergence and the Wang-Landau algorithm.
  • 11:30 am - 12:15 pm EDT
    A Mean-Field Games Laboratory for Generative Modeling: Implications for Robust Generative Algorithms
    11th Floor Lecture Hall
    • Speaker
    • Markos Katsoulakis, University of Massachusetts Amherst
    • Session Chair
    • Petr Plechac, University of Delaware
    Abstract
    the first part of the talk, we demonstrate the versatility of mean-field games (MFGs) as a mathematical framework for explaining, enhancing, and designing generative models. We establish connections between MFGs and major classes of flow- and diffusion-based generative models by deriving continuous-time normalizing flows, score-based models, and Wasserstein gradient flows through different choices of particle dynamics and cost functions. Second, from a UQ perspective, relying on a new Wasserstein uncertainty propagation theorem, we show that score-based generative models (SGMs) are provably robust to multiple sources of error in their practical implementation. The regularizing properties of Hamilton-Jacobi-Bellman equations in the MFG formulation of SGMs are the key ingredient of this analysis.
  • 12:25 - 12:30 pm EDT
    Group Photo (Immediately After Talk)
    11th Floor Lecture Hall
  • 12:30 - 2:00 pm EDT
    Lunch/Free Time
  • 2:00 - 2:45 pm EDT
    Asymptotic Problems for Stochastic Wave Equations with Constraints
    11th Floor Lecture Hall
    • Speaker
    • Sandra Cerrai, University of Maryland
    • Session Chair
    • Amber Puha, CSU San Marcos
    Abstract
    I will s bytart reviewing some results obtained in collaboration with Z. Brzezniak about the small mass limit for stochastic wave equations subject to suitable functional constraints. Then, I will outline more recent developments achieved in collaboration with M. Xie on constrained systems of stochastic partial differential equations
  • 3:00 - 3:15 pm EDT
    Coffee Break
    11th Floor Collaborative Space
  • 3:15 - 4:00 pm EDT
    Proximal Optimal Transport Divergences for Generative Modeling
    11th Floor Lecture Hall
    • Speaker
    • Luc Rey-Bellet, UMass Amherst
    • Session Chair
    • Amber Puha, CSU San Marcos
    Abstract
    We introduce families of information theoretic divergences between probability measure which are constructed as Moreau-Yosida regularization of f-divergence (e.g. KL-divergences) with a Wasserstein metrics. We discuss the fundamental properties of those divergence as well as their applications to generative modeling and their analysis using mean-field games tools.
  • 4:15 - 5:00 pm EDT
    Stochastic Optimization Algorithms with Heavy Tailed Input
    11th Floor Lecture Hall
    • Speaker
    • Jose Blanchet, Stanford
    • Session Chair
    • Amber Puha, CSU San Marcos
    Abstract
    We first explain why statistical analysis of stochastic optimization algorithms with heavy-tailed input arises naturally in applications. In fact, we will argue that models that assume infinite variance gradient estimators in stochastic gradient descent are appropriate depending on easy-to-monitor features of historical data and on the spatial and temporal scales over which the algorithm will be deployed (even if models have finite variance in theory). We will then discuss inference tools that can be applied to monitor convergence of stochastic optimization algorithms based on several asymptotic statistics. The results that we will present include the first weak convergence analysis of stochastic gradient descent with infinite variance, extending results which assume finite variance or homogeneous and additive gradient noise. Based on joint work with Aleks Mijatovic, Wenhao Yang, Joost Jorritsma, Bert Zwart
  • 5:00 - 6:30 pm EDT
    Reception
    11th Floor Collaborative Space
Saturday, September 14, 2024
  • 9:00 - 9:45 am EDT
    Coarse Correlated Equilibria in Mean Field Games
    11th Floor Lecture Hall
    • Speaker
    • Markus Fischer, University of Padua
    • Session Chair
    • Wlodzimierz Bryc, University of Cincinnati
    Abstract
    In the context of finite horizon mean field games with continuous time dynamics driven by additive Wiener noise, we introduce a notion of coarse correlated equilibrium in open-loop strategies. For non-cooperative many-player games, a coarse correlated equilibrium can be seen as a lottery on strategy profiles run according to a publicly known mechanism by a moderator who uses the (non-public) lottery outcomes to tell players in private which strategy to play. Players have to decide in advance whether to pre-commit to the mediator's recommendations or to play without seeing them. We justify our definition by showing that any coarse correlated solution of the mean field game induces approximate coarse correlated equilibria for the underlying N-player games. An existence result for coarse correlated mean field game solutions, not relying on the existence of classical solutions, will be given; an explicitly solvable example will be discussed as well. Joint work with Luciano Campi and Federico Cannerozzi (University of Milan "La Statale").
  • 10:00 - 11:00 am EDT
    Poster Session/Coffee Break
    Poster Session - 10th Floor Collaborative Space
  • 11:00 - 11:45 am EDT
    Aspects of the Cutoff Phenomenon for Diffusions
    11th Floor Lecture Hall
    • Speaker
    • Djalil Chafai, Universite Paris-Dauphine
    • Session Chair
    • Wlodzimierz Bryc, University of Cincinnati
    Abstract
    The cutoff phenomenon, conceptualized in the context of finite Markov chains, states that for certain linear evolution equations, started from a point, the distance towards a long time equilibrium may become more and more abrupt in high dimensional state spaces and for certain choices of initial conditions. This can be seen as a critical competition between trend to equilibrium and initial condition. This talk is about the cutoff phenomenon for few classes of linear and nonlinear diffusions.
  • 12:00 - 12:45 pm EDT
    Large Deviations and Calculus of Variations for Some Pure Jump Interacting Particle Systems
    11th Floor Lecture Hall
    • Speaker
    • Ruoyu Wu, Iowa State University
    • Session Chair
    • Wlodzimierz Bryc, University of Cincinnati
    Abstract
    Sample path large deviation principles (LDP) are established for some pure jump stochastic processes arising from queueing systems, including M/M/1+M, M/M/n+M, and Join-the-Shortest-Queue. The process of evolution suffers from features of infinite dimensional dynamics, vanishing jump rates (near the boundary), and/or discontinuous statistics (at the boundary), which pose challenges on the variational representation and weak convergence approach, in particular the uniqueness argument. Rare events of interest are analyzed by solving the related calculus of variations problems written in terms of the LDP rate functions. If time permits, the Join-the-Shortest-Queue-d (power-of-d) queueing system will be discussed, including conjectures on the LDP and establishment of moderate deviation principles. This is based on several joint works with Rami Atar, Amarjit Budhiraja, Paul Dupuis, Eric Friedlander, and Zhenhua Wang.
  • 1:00 - 2:30 pm EDT
    Lunch/Free Time
  • 2:30 - 3:15 pm EDT
    Biochemical Reaction Networks and Reflected Diffusions
    11th Floor Lecture Hall
    • Virtual Speaker
    • Ruth Williams, University of California, San Diego
    • Session Chair
    • Mickey Salins, Boston University
    Abstract
    Leite and Williams have proposed certain reflected diffusion processes as approximations to continuous time Markov chain models frequently used to model biochemical reaction networks. These diffusions live in the positive orthant of a d-dimensional space and are confined there by a smoothly varying oblique reflection field on the boundary. Leite and Williams showed that, under mild conditions, these diffusions can be obtained as weak limits of certain jump-diffusion extensions of the traditional Langevin approximations, and therefore called these constrained Langevin approximations. In this talk, we will review this approximation and describe some progress on proving error estimates for strong versions of this approximation and also describe some remaining open problems. Part of this work is joint with Felipe Campos.
  • 3:30 - 4:00 pm EDT
    Coffee Break
    11th Floor Collaborative Space
  • 4:00 - 4:45 pm EDT
    Particle-Based Stochastic Reaction-Diffusion Models: Mean field limits and fluctuation corrections.
    11th Floor Lecture Hall
    • Speaker
    • Konstantinos Spiliopoulos, Boston University
    • Session Chair
    • Mickey Salins, Boston University
    Abstract
    Particle-based stochastic reaction-diffusion (PBSRD) models are a popular approach for studying biological systems involving both noise in the reaction process and diffusive transport. In this work we derive coarse-grained deterministic partial integro-differential equation (PIDE) models that provide a mean field approximation to the volume reactivity PBSRD model, a model commonly used for studying cellular processes. We formulate a weak measure-valued stochastic process (MVSP) representation for the volume reactivity PBSRD model, demonstrating for a simplified but representative system that it is consistent with the commonly used Doi Fock Space representation of the corresponding forward equation. We then prove, (a): the convergence of the general volume reactivity model MVSP to the mean field PIDEs in the large-population (i.e. thermodynamic) limit, and (b): the next order fluctuation correction to the mean field limit, which satisfies systems of stochastic PIDEs with Gaussian noise. Numerical examples are presented to illustrate how such approximations can enable the accurate estimation of higher order statistics of the underlying PBSRD model. Time permitting, I will also discuss the reduction of the underdamped to the overdamped case in the setting PBSRD models. This is joint work with Samuel Isaacson, Max Heldman, Jingwei Ma, Qianhan Liu and Chen Yao.
  • 6:00 - 8:30 pm EDT
    Dinner
    - Venue TBD
    Abstract
    This dinner has an associated cost and is by RSVP only. Please contact mariam_han@brown.edu if you would like to register for the dinner, and she will provide you with a link to the payment portal. Cut-off to RSVP is September 5
Sunday, September 15, 2024
  • 9:00 - 9:45 am EDT
    In Search of Markov Solutions
    11th Floor Lecture Hall
    • Speaker
    • Vivek Borkar, IIT Bombay, India
    • Session Chair
    • Arnab Ganguly, Louisiana State University
    Abstract
    This talk will summarise recent contributions to two strands of research - mimicking one dimensional marginals of random processes by Markov processes, and selecting a Markov family of solutions for degenerate diffusions with non-unique solutions (also known as Markov selection).
  • 10:00 - 10:30 am EDT
    Coffee Break
    11th Floor Collaborative Space
  • 10:30 - 11:15 am EDT
    Estimating Rare Event Probabilities in Reflecting Brownian Motion
    11th Floor Lecture Hall
    • Speaker
    • Kevin Leder, University of Minnesota
    • Session Chair
    • Arnab Ganguly, Louisiana State University
    Abstract
    Reflecting Brownian motion (RBM) is a stochastic process that behaves like a Brownian motion in the interior of its domain and is pushed into the interior whenever it reaches the boundary of its domain. RBM’s in the positive orthant were first introduced by Harrison and Reiman 1981, and arise naturally in a wide variety of settings, e.g., heavy traffic queueing networks. A difficult question that has received a significant amount of attention is identifying the asymptotics for tail probabilities associated with RBM in the positive orthant. In this work we focus on the specific tail probability that a stable RBM started near the origin exits a large box before returning to the origin. We develop particle based algorithms to estimate this probability. Using results of Dean and Dupuis 2008 we are able to develop algorithms that efficiently estimate this tail probability in two dimensions. In three and higher dimensions, we are not able to construct an efficient estimator, but we do construct estimators that are provably superior (in an asymptotic sense) to standard Monte Carlo. Numerical results show the benefits of our algorithm to standard Monte Carlo. This is based on joint work with Xin Liu and Zicheng Wang.
  • 11:30 am - 12:15 pm EDT
    Reflecting Diffusions in Curved Nonsmooth Domains
    11th Floor Lecture Hall
    • Speaker
    • Cristina Costantini, University of Chieti-Pescara
    • Session Chair
    • Arnab Ganguly, Louisiana State University
    Abstract
    Reflecting diffusions arise in many applications: from stochastic networks, to singular stochastic control, to the motion of physical particles, etc.. In many examples the domain in which the reflecting diffusion is to be confined is nonsmooth or the direction of reflection varies nonsmoothly: in these cases it is not obvious that a reflecting diffusion with the prescribed direction of reflection exists and is uniquely characterized. After reviewing the literature, in which the works by Dupuis and Ishii play a central role, I will discuss how a recent ergodic theorem for inhomogeneous killed Markov chains allows to extend the 1993 Dupuis and Ishii results to some new classes of domains and directions of reflection. In particular one can obtain existence and uniqueness of a semimartingale reflecting diffusion in a piecewise smooth domain in dimension 2, possibly with cusps, under optimal conditions on the directions of reflection, and one can uniquely characterize obliquely reflecting Brownian motion in some piecewise smooth cones. The talk is based on joint works with T.G. Kurtz.
  • 12:30 - 2:00 pm EDT
    Lunch/Free Time
  • 2:00 - 2:45 pm EDT
    Using Weak Convergence Methods to Establish Exit Time Asymptotics for a Small Noise Infinite-dimensional System
    11th Floor Lecture Hall
    • Speaker
    • David Lipshutz, Flatiron Institute
    • Session Chair
    • Tao Pang, North Carolina State University
    Abstract
    Dynamical systems with small noise arise in a wide variety of applications. In such applications, we'd like to know how long it takes the small noise system to escape stable equilibra of the corresponding deterministic system. For finite-dimensional systems, these "exit times" are typically established by proving large deviation principles that are uniform over compact sets. However, for infinite-dimensional systems, bounded sets are no long compact and this approach does not naturally extend. Here, in the context of a small noise stochastic delay differential equation with strong solutions whose natural state space is infinite-dimensional, we show how the weak convergence method that was pioneered by Paul Dupuis can be used to prove a large deviation principle that is uniform over bounded sets. In turn, this enables us to prove exit time asymptotics for the small noise stochastic delay differential equation.
  • 3:00 - 3:45 pm EDT
    Renormalized relative entropies and an H-theorem for interacting diffusions on sparse graphs
    11th Floor Lecture Hall
    • Speaker
    • Kavita Ramanan, Brown University
    • Session Chair
    • Tao Pang, North Carolina State University
    Abstract
    We consider a class of conditional McKean-Vlasov processes that arise in the study of interacting Langevin diffusions on regular trees. We establish an H-theorem that characterizes the long-time behavior of these processes. Specifically, we show that a certain function that arises when taking the limit of certain renormalized relative entropies serves as a global Lyapunov function for the associated measure flow. We also provide counterexamples to highlight some subtleties in the approach, and discuss some open problems. This is joint work with Kevin Hu.

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