2025Activity reportProject-Team​​​‌PASTA

4.1 Geophysics​‌

Geophysics is a domain​​ which requires the application​​​‌ of a broad range​ of mathematical tools related​‌ to probability and statistics​​ while more and more​​​‌ data are collected. There​ are several directions in​‌ which we develop our​​ methodology in relation with​​​‌ practitioners in the field:​

• Avalanches (snow or rock)​‌ present intricate dynamical properties,​​ with a wide variety​​​‌ of behaviors that largely​ depend on their environments.​‌ To model such phenomena,​​ we apply tools from​​​‌ fragmentation theory, stochastic calculus,​ partial differential equations and​‌ branching processes. Our techniques​​ and developments differ from​​​‌ existing approaches (as we​ are considering the behavior​‌ at the microscopic scale​​ and we are following​​​‌ the evolution of a​ typical particle) and introduce​‌ innovative solutions. Thus, the​​ approach we consider is​​​‌ new and paves the​ way to considering and​‌ constructing rigorous mathematical models​​ and simulation procedures able​​​‌ to reproduce and control​ the real phenomenon by​‌ introducing more and more​​ issues in the models.​​​‌
• Understanding the behavior of​ subsurface and surface fluids​‌ is a major challenge​​ in geophysics. We deal​​​‌ with two main axes:​ (1) using tools for​‌ spatial Bayesian statistics which​​ consists in detecting the​​​‌ sources of the various​ components of fluids from​‌ their hydrogeochemical data, and​​ (2) developing the suitable​​​‌ methodological and numerical tools​ to simulate diffusion processes​‌ (pollutant, water...) moving in​​ heterogenous media in the​​​‌ presence of interfaces.
• Earthquake​ forecasting is notoriously difficult.​‌ To grasp the statistical​​ distribution of seismic hazards,​​​‌ we consider setting up​ tools to detect seismic​‌ faults using marked point​​ processes. Such a project​​​‌ presents challenging aspects concerning​ both the inference and​‌ the simulation of the​​ processes.

On such topics,​​​‌ we hold long standing​ interdisciplinary collaborations with INRAE​‌ Grenoble, the RING Team​​ (GeoRessources, Université de Lorraine),​​​‌ IMAR (Institute of Mathematics​ of the Romanian Academy)​‌ in Bucharest.

4.2 Astronomy​​

We have longstanding and​​​‌ continuous cooperation with astronomers​ and cosmologists in France,​‌ Spain and Estonia. In​​ particular, we are interested​​​‌ in using spatial statistics​ tools to detect galaxies​‌ and other star patterns​​ such as filaments detection.​​​‌ Such developments require us​ to design specific point​‌ processes giving appropriate morpho-statistical​​ distributions, as well as​​ specific inference algorithms which​​​‌ are based on Monte‌ Carlo simulations and able‌​‌ to handle the large​​ volume of data.

4.3​​​‌ Complex systems for healthcare,‌ insurance, social networks and‌​‌ telecommunication networks

Graphs are​​ essential to model complex​​​‌ systems such as the‌ relations between agents, the‌​‌ spatial distribution of points​​ that are connected such​​​‌ as stars, the connections‌ in telecommunication networks, and‌​‌ so on. We develop​​ various directions of the​​​‌ study of random graphs‌ that are motivated by‌​‌ a large class of​​ applications:

• The success of​​​‌ organ transplant operations depends‌ on their capacity to‌​‌ comply in real time,​​ with sharp compatibility constraints.​​​‌ Here, vertices represent at‌ any given time receivers‌​‌ and donors, while edges​​ represent compatibilities. To improve​​​‌ the quality of such‌ life-saving medical acts, we‌​‌ work on the optimization​​ and control of organ​​​‌ transplant systems by stochastic‌ matching models, namely, queueing‌​‌ models in which elements​​ are matched in real​​​‌ time, following prescribed compatibility‌ constraints.
• The modeling of‌​‌ epidemics, viruses on computer​​ networks and message percolation​​​‌ on large social networks‌ can be addressed using‌​‌ the theory of large​​ graph asymptotic on random​​​‌ graphs. In particular, we‌ work on Markov exploration‌​‌ algorithms on large Configuration​​ Model graphs, to propose​​​‌ weak, but tractable approximations‌ of such propagation phenomena‌​‌ on large networks.
• We​​ have longstanding collaborations in​​​‌ the domain of performance‌ analysis of telecommunication networks.‌​‌ In particular, we worked​​ on the modeling and​​​‌ analysis of queuing systems‌ with reneging with applications‌​‌ to real-time networking; on​​ the performance analysis of​​​‌ parallel service systems, and‌ the large-network analysis of‌​‌ CDMA-type (Code Division Multiple​​ Access) communication protocols, using​​​‌ random graph modeling. We‌ also considered ad-hoc networking‌​‌ and the Internet of​​ Things (IoT). Using graph​​​‌ and game theory techniques,‌ we aim at a‌​‌ proper definition, and dynamical​​ analysis, of the notion​​​‌ of trust between agents‌ of these networks.
• Using‌​‌ random field models on​​ graphs, we have considered​​​‌ the simulation and inference‌ of the relations between‌​‌ bibliographical data related to​​ scientific literature. This provides​​​‌ us with an application‌ of our techniques in‌​‌ the field of dynamical​​ evolution of networks.
• We​​​‌ study the spatial distribution‌ of random $T$-tessellation‌​‌ with the aim of​​ providing models for agricultural​​​‌ parcels. Again, such a‌ problem presents challenging aspects‌​‌ both for simulation and​​ inference.
• Finally, we consider​​​‌ personalized recommendation systems for‌ insurance which are based‌​‌ on life events, using​​ self-excited processes. We developped​​​‌ techniques based on Hawkes‌ processes and improve the‌​‌ existing approaches.

We have​​ longstanding collaborations on these​​​‌ topics with Agence de‌ Biomédecine (ABM), Le Foyer‌​‌ (insurance company, Luxembourg), INRAE​​ (Avignon), Lip 6, UTC,​​​‌ LORIA (computer science laboratory,‌ Nancy), University of Buenos‌​‌ Aires, Northwestern University and​​ LAAS (CNRS, Toulouse).

4.4​​​‌ Digital Humanities

Digital Humanities‌ represents an interdisciplinary field‌​‌ of research. We are​​ interested in developing suitable,​​​‌ automatic tools to help‌ experts to study the‌​‌ ideas contained in antique​​ texts. Together with historians​​​‌ of antiquity, we considered‌ one of the founding‌​‌ texts of political sciences,​​​‌ the Politics of Aristotle.​ To fulfill our purposes,​‌ we consider techniques from​​ the history of antiquity,​​​‌ machine learning, and statistics.​ This presents some technological​‌ challenges to develop suitable​​ tools to load and​​​‌ manipulate the data.

This​ research was supported by​‌ the Inria Exploratory Reasearch​​ Action Apollon (2022-2024) and​​​‌ by CNRS. It involves​ collaboration with researchers from​‌ Archimède (Universities of Strasbourg​​ and Haute-Alsace), IRIMAS and​​​‌ CRESAT (Université de Haute-Alsace)​ and University of Pavia.​‌

6.1 New platforms

Participants:​​​‌ Antoine Lejay, Radu​ Stoica, Saïd Toubra​‌.

DRLIB is a​​ C++ library built for​​​‌ performing modeling, simulation and​ statistical inference based on​‌ marked point processes with​​ interaction. This library is​​​‌ the result of a​ joint project of Radu​‌ Stoica with Didier Gemmerlé​​ (CNRS research engineer at​​​‌ IECL).

Palamède aims at​ being a collaborative plateform​‌ to vizualize, annotate and​​ analyze texts from the​​​‌ point of view of​ experts in history, philology​‌ or more generally in​​ social sciences. The short​​​‌ term goals are to​ incorporate tools from Artifical​‌ Intelligence to ease the​​ study of texts. This​​​‌ plateform is supported by​ the ADT (Action de​‌ développement Technologique) Apollon.

7.1 Analysis​​​‌ and simulation of Stochastic​ Differential Equations: thresholds and​‌ singularities

Participants: Julia Budzinski​​, Madalina Deaconu,​​​‌ Antoine Lejay, Sara​ Mazzonetto.

The numerical​‌ approximation of Stochastic Differential​​ Equations (SDEs) and in​​​‌ particular new methodologies to​ approximate hitting times of​‌ SDEs is a challenging​​ problem which is important​​​‌ for a large class​ of practical issues such​‌ as: geophysics, finance, insurance,​​ biology, etc.

With Samuel​​​‌ Herrmann (Université de Bourgogne),​ Madalina Deaconu achieved significant​‌ progress on this topic​​ by developing new methods​​​‌ that are both simple​ to implement and efficient.​‌ We pursued this topic​​ by developping the approximation​​​‌ of diffusion exit times​ from bounded domains using​‌ a rejection-based random walk​​ on truncated spheroids. The​​​‌ proposed approach relies on​ an acceptance–rejection procedure applied​‌ to random walk trajectories.​​ These trajectories, modeled as​​​‌ random walks on spheroids​ that approximate the paths​‌ of Brownian motion, were​​ originally introduced to solve​​​‌ the Brownian exit problem​ in $d$-dimensional space.​‌ In this approach, we​​ introduce a substantial modification​​​‌ by replacing spheroids with​ truncated spheroids, which enables​‌ the extension of results​​ obtained for Brownian paths​​​‌ to more general diffusion​ processes.

Madalina Deaconu ,​‌ together with Samuel Herrmann​​ (Université de Bourgogne) and​​​‌ Cristina Zucca (University of​ Torino), continued their work​‌ on the exact simulation​​ of the hitting times​​​‌ of multi-dimensional diffusions.

Existence​ and uniqueness results for​‌ one-dimensional stochastic processes solution​​ to SDEs, are important​​​‌ because lack of uniqueness​ may affect approximation or​‌ inference results. In an​​ ongoing work, Sara Mazzonetto​​ , Alexis Anagnostakis (IECL​​​‌ Metz) and Pierre Etoré‌ (LJK Grenoble) are dealing‌​‌ with different questions about​​ the non-uniqueness of solutions​​​‌ for processes solution to‌ SDEs with a diffusion‌​‌ coefficient admitting jumps and​​ becoming negative. We tackle​​​‌ a conjecture that has‌ been open since the‌​‌ 80's. We have obtained​​ a partial answer and​​​‌ we are seeking for‌ the link with sticky-skew‌​‌ diffusions. In the last​​ year we obtained an​​​‌ alternative proof. We are‌ exploring different approaches to‌​‌ extend the class of​​ coefficients we can deal​​​‌ with.

On another ongoing‌ work with Benoît Nieto‌​‌ (former postdoc at École​​ Polytechnique, now working at​​​‌ ESILV), Sara Mazzonetto is‌ considering theoretical results on‌​‌ existence and uniqueness of​​ solutions to SDEs with​​​‌ singularities: degenerating diffusion coefficient,‌ distributional drifts, or discontinuous‌​‌ coefficients. We apply these​​ results to prove strong​​​‌ existence and uniqueness for‌ solution to several-regimes CIR‌​‌ (Cox-Ingersoll-Ross) which presents both​​ degenerate diffusion and discontinuous​​​‌ coefficients. The inference for‌ this model has already‌​‌ given rise to a​​ publication 15.

Julia​​​‌ Budzinski , under the‌ supervision of Madalina Deaconu‌​‌ and Sara Mazzonetto ,​​ is considering a probabilistic​​​‌ numerical approximation scheme for‌ SDEs with singular coefficients.‌​‌ Althought some convergence results​​ exist for the Symetrized​​​‌ Euler scheme applied to‌ CIR with continuous coefficients‌​‌ and for the Euler​​ scheme applied to SDE​​​‌ with discontinuous coefficients, no‌ such convergence results are‌​‌ available for the Symetrized​​ Euler scheme applied to​​​‌ CIR with discontinuous coefficients.‌

Madalina Deaconu , Lucian‌​‌ Beznea (IMAR, Bucharest) and​​ Oana Lupaşcu-Stamate (Gheorghe Mihoc–Caius​​​‌ Iacob Institute of Mathematical‌ Statistics and Applied Mathematics‌​‌ of the Romanian Academy,​​ Bucharest) are developing a​​​‌ stochastic approach for the‌ two-dimensional Navier-Stokes equation in‌​‌ a bounded domain. More​​ precisely we consider the​​​‌ vorticity equation and construct‌ a specific non-local branching‌​‌ process. This approach is​​ new and may conduct​​​‌ to important advances as‌ it will also results‌​‌ in a new numerical​​ algorithm if successful.

In​​​‌ particular, we obtained several‌ results concerning the construction‌​‌ of a duality -​​ time reversal process and​​​‌ also in the development‌ of a numerical algorithm‌​‌ with a non-local branching​​ process involving the creation​​​‌ and disappearance of particles‌ that mimic the physics‌​‌ of the vorticity in​​ the boundary layer.

7.2​​​‌ Stochastic dynamics with jumps‌

Participants: Madalina Deaconu,‌​‌ Antoine Lejay.

We​​ have a strong interest​​​‌ in the fragmentation equation‌ for understanding snow or‌​‌ rock avalanches. Our point​​ of view is to​​​‌ explore the probabilistic representations‌ of transport equations in‌​‌ this framework as well​​ as the possibilities they​​​‌ offer.

Madalina Deaconu and‌ Antoine Lejay , together‌​‌ with Gaetano Agazzotti (former​​ intern in the team),​​​‌ have studied in 12‌ the evolution of the‌​‌ moments of a self-similar​​ fragmentation equation from an​​​‌ analytic viewpoint. In particular,‌ we have shown existence‌​‌ for an initial condition​​ which is a measure.​​​‌ We have proved rigorously‌ its asymptotic behavior.

Madalina‌​‌ Deaconu , together with​​ Oana Lupaşcu-Stamate (Gheorghe Mihoc–Caius​​​‌ Iacob Institute of Mathematical‌ Statistics and Applied Mathematics‌​‌ of the Romanian Academy),​​​‌ studied the asymptotic behaviour​ of an avalanche model​‌ through a discret non-conservative​​ binary coagulation-fragmentation equation 13​​​‌. The model develops​ self-organized critical systems and​‌ in particular a simple​​ sand pile model. This​​​‌ approach furnishes a new​ interpretation of the avalanche​‌ phenomena by handling stochastic​​ differential equations with jumps.​​​‌ The model is completed​ by numerical simulations.

7.3​‌ Inference of singular or​​ regular Stochastic Differential Equations​​​‌

Participants: Julia Budzinski,​ Antoine Lejay, Sara​‌ Mazzonetto.

Antoine Lejay​​ and Sara Mazzonetto continued​​​‌ to improve their work​ on an expansion of​‌ the maximum likelihood estimator​​ using formal series expansions​​​‌ 31 with a view​ toward stochastic differential equations​‌ with singular coefficients. The​​ aim of this work​​​‌ is to understand the​ lack of Gaussianity in​‌ the non-asymptotic regime.

Sara​​ Mazzonetto and Benoit Nieto​​​‌ (ESILV), consider several-regimes CKLS​ (Chan-Karolyi–Longstaff– Sanders) dynamics (including​‌ Cox-Ingersoll-Ross model) and studied​​ parameter estimation from high-frequency​​​‌ observations. This result allows​ to consider new dynamics​‌ and recover the previously​​ treated dynamics. During this​​​‌ year, improvement of the​ results have been provided​‌ leading to a publication​​ 15.

With Paolo​​​‌ Pigato (University Tor Vergata,​ Roma), Sara Mazzonetto worked​‌ on new estimators from​​ low frequency observations for​​​‌ the parameters of several​ regimes threshold models which​‌ show mean-reversions features 37​​. They consider also​​​‌ non-stationary regimes.

Julia Budzinski​ is working on using​‌ these results, among others​​ such as 36,​​​‌ for modeling Realized Volatility​ data. The objective is​‌ to perform a comparative​​ analysis of exponential Ornstein-Uhlenbeck​​​‌ and CIR models with​ and without threshold using​‌ both simulated and real​​ Realized Volatility datasets. To​​​‌ this end, she is​ developing algorithms to jointly​‌ estimate drift, volatility and​​ thresholds and then test​​​‌ the presence of one​ or more thresholds in​‌ the drift. One of​​ the statistical tests for​​​‌ thresholds detection is based​ on Monte Carlo methods​‌ which require the ability​​ to simulate the underlying​​​‌ process. The Euler scheme​ is used for the​‌ Ornstein-Uhlenbeck while the symmetrized​​ Euler scheme is used​​​‌ for the CIR. Comparison​ of the models is​‌ based on statistical criteria​​ that penalized the model​​​‌ complexity such as the​ Akaike Information Criterion (AIC).​‌

Sara Mazzonetto and Alexis​​ Anagnostakis (postdoc at IECL​​​‌ Metz) have been extending​ their respective results on​‌ high-frequency approximation of the​​ local time of sticky-oscillating-skew​​​‌ diffusion processes. Via some​ new functional limit theorems​‌ for sticky diffusions, they​​ estimate the parameters of​​​‌ stickiness and/or skewness 27​. The main goal​‌ is to reach rates​​ of convergence for sticky​​​‌ diffusions and so extend​ the results in the​‌ publication 16. We​​ improved a partial interesting​​​‌ result for sticky Brownian​ motion presented in 34​‌.

7.4 Hawkes processes​​ for plant deases

Participants:​​​‌ Madalina Deaconu.

Hawkes​ point processes model phenomena​‌ in which the occurrence​​ of an event triggers​​​‌ the arrival of other​ events of the same​‌ type. With Katarzyna Adamczyk​​ (INRAE), Madalina Deaconu proposed​​​‌ a modeling based on​ this process in order​‌ to study apple scab,​​ a disease of apple​​ trees caused by the​​​‌ pathogenic fungus Venturia inaequalis‌ 22. The Hawkes‌​‌ model proposed for the​​ emission of fungal spores​​​‌ takes into account meteorological‌ covariates that may trigger‌​‌ this emission. The results​​ show that the estimator​​​‌ of the conditional intensity‌ of the process can‌​‌ be considered as a​​ relevant indicator of the​​​‌ risk of contamination of‌ apple trees.

Work is‌​‌ in progress on this​​ topic as we are​​​‌ developping Hawkes process with‌ time-varying baseline intensity influenced‌​‌ by dynamic covariates. The​​ main objective of the​​​‌ project is to study‌ the asymptotic properties of‌​‌ estimators in this model.​​ We will work in​​​‌ a Bayesian framework, aiming‌ for posterior contraction and,‌​‌ if possible, selection consistency​​ under sparsity-inducing priors, while​​​‌ benefiting from natural uncertainty‌ quantification.

7.5 Application of‌​‌ Approximate Bayesian Computation algorithms​​ for parameter estimation for​​​‌ Gibbs point processes based‌ on partly missing data‌​‌

Participants: Nathan Gillot,​​ Radu Stoica.

In​​​‌ galactic patterns, some of‌ the data is often‌​‌ missing and methods to​​ characterise such patterns need​​​‌ to be developed. We‌ focus on Gibbs point‌​‌ processes in a bounded​​ region $W={\mathrm{W‌}}_X\cup W_{\mathrm{Y‌}}$, observable only in‌​‌ $W_Y$. In​​ this situation, the likelihood​​​‌ of the underlying point‌ process cannot be derived‌​‌ from the available observations,​​ unless simulated data is​​​‌ produced via Markov Chain‌ Monte Carlo (MCMC) procedures‌​‌ in the region ${\mathrm{W}}_X$, where direct​​​‌ observations are not available.‌ This operation increases the‌​‌ general computational cost and​​ the convexity of the​​​‌ likelihood can not be‌ guaranteed. In order to‌​‌ overcome this drawback, Radu​​ Stoica , Nathan Gillot​​​‌ , Didier Gemmerlé (IECL,‌ Université de Lorraine) and‌​‌ Aila Särkkä (Chalmers University,​​ Sweden) used an Approximate​​​‌ Bayesian Computation (ABC) framework‌ to estimate the model‌​‌ parameters based on partly​​ missing data. This framework​​​‌ allows a theoretical construction‌ of Metropolis-Hastings dynamics that‌​‌ samples from the joint​​ distribution of the unobserved​​​‌ pattern and the parameter‌ of interest, conditionally on‌​‌ the observed data. The​​ theoretical properties of the​​​‌ proposed dynamics enable the‌ construction of different approximate‌​‌ algorithms that exhibit good​​ convergence properties. The proposed​​​‌ method is applied to‌ simulated and real data‌​‌ 23.

7.6 Modeling​​ in geophysics: fault observations​​​‌ and inference

Participants: Radu‌ Stoica.

Radu Stoica‌​‌ with Guillaume Caumon, Fabrice​​ Taty-Moukati and François Bonneau​​​‌ (all at GeoRessources, Université‌ de Lorraine) integrated human‌​‌ interpretation to downscale machine​​ learning-based fault likelihood images​​​‌ into potential fault networks‌ using the Candy Model,‌​‌ a marked point process​​ that simulates networks consistently​​​‌ with input images 21‌. Parameters are inferred‌​‌ from expert networks using​​ the ABC Shadow algorithm.​​​‌ Applied to three fault‌ interpretations, the method successfully‌​‌ generates alternatives, though better​​ control of branching and​​​‌ relay zones is needed.‌ The workflow bridges computational‌​‌ uncertainty quantification and human-based​​ approaches for subsurface forecasts.​​​‌

With Amandine Fratani, Guillaume‌ Caumon, Jeremie Giraud, Romain‌​‌ Baville, Chiara-Luna Prest, Christophe​​ Antoine (GeoRessources, Université de​​​‌ Lorraine), we are interested‌ in using expert rules‌​‌ to model fault networks​​​‌ from incomplete data using​ graph formalism, where nodes​‌ represent fault observations and​​ edges indicate potential associations.​​​‌ This approach, previously applied​ to 2D seismic images,​‌ is adapted here for​​ borehole data. Three new​​​‌ expert rules incorporate borehole-specific​ information: orientation (dip and​‌ dip direction), position, and​​ aperture. A new sampling​​​‌ algorithm efficiently manages large​ drilling campaigns in mining,​‌ producing fault scenarios consistent​​ with these rules.

Finally,​​​‌ with Amandine Fratani, Guillaume​ Caumon, Jeremie Giraud (GeoRessources,​‌ Université de Lorraine) and​​ Vitaliy Ogarko, Mark Jessel,​​​‌ Guillaume Pirot (Centre for​ Exploration Targeting, University of​‌ Western Australia), we consider​​ the creation of a​​​‌ synthetic training database for​ fault observations association. Geological​‌ models in sedimentary basins​​ are constrained by interpreting​​​‌ faults and horizons in​ seismic and drillhole data.​‌ Data sparsity allows multiple​​ fault networks from a​​​‌ single observation set. Graph​ formalism with nodes representing​‌ observations and edges carrying​​ association potentials addresses this.​​​‌ Machine learning, specifically Random​ Forest, can compute these​‌ potentials, but limited open-access​​ structural models restrict its​​​‌ application. This work develops​ a synthetic structural model​‌ database featuring normal faults​​ using modified Noddy code.​​​‌ Faults are grouped into​ families with similar orientations​‌ defined by mean dip​​ and dip direction. Individual​​​‌ fault orientations are sampled​ from a Kent distribution.​‌ Resulting models are smoothed​​ in geological software, then​​​‌ sampled to train a​ Random Forest for retrieving​‌ association potentials.

7.7 Exploration​​ algorithms of large random​​​‌ graphs

Participants: Pascal Moyal​.

We have pursued​‌ our research activity on​​ the Markovian analysis of​​​‌ various Markovian exploration algorithms​ on random graphs, analyzed​‌ and/or approximated to the​​ large graph limits, using​​​‌ scaling limits of stochastic​ processes, on three distinct​‌ classes of random graphs:​​ Configuration models, Stochastic​​​‌ block models, and​ Preferential attachment models.​‌

In a revision of​​ 30, with Vincent​​​‌ Robin and Mohamed Habib​ Dialo Aoudi (UTC), we​‌ enriched our theoretical results​​ with a tractable numerical​​​‌ scheme for the competitive​ ratio of online matching​‌ algorithms on large graphs.​​ Using hydrodynamic limits for​​​‌ the Configuration model, matching​ coverage is computed by​‌ solving ODEs. We aim​​ at extending this to​​​‌ exploration algorithms such as​ breadth-first search and coloring​‌ on random graphs.

For​​ multiclass online Stochastic block​​​‌ models, 17 gives necessary​ and sufficient conditions for​‌ the existence of a​​ perfect matching infinitely often,​​​‌ and moment bounds for​ the number of unmatched​‌ nodes, by Lyapunov techniques.​​

With Mariana Olvera-Cravioto (University​​​‌ of North Carolina), we​ are investigating the connected​‌ out-component of vertices in​​ large oriented preferential attachment​​​‌ graphs (Barabasí-Albert model). Using​ Markov in-depth exploration and​‌ coupling methods, we show​​ that the local limits​​​‌ follow a multi-type Galton-Watson​ process. This has crucial​‌ implications for the asymptotic​​ analysis of preferential attachment​​​‌ models in epidemiological and​ social media applications.

7.8​‌ Optimization of queueing systems:​​ Reinforcement learning and Markov​​​‌ control

Participants: Pascal Moyal​.

Pascal Moyal has​‌ dedicated an important part​​ of his research activity​​​‌ on two ongoing projects​ on the stochastic optimization​‌ and control of queueing​​ systems.

First, with Céline​​ Comte (LAAS-CNRS), we generalized​​​‌ quasi-reversibility for Continuous-time Markov‌ chains (CTMC's), enabling simple‌​‌ quasi-product form representations of​​ stationary distributions, a crucial​​​‌ feature for long-run simulation‌ and equilibrium analysis. This‌​‌ general quasi-reversibility property holds​​ in particular for a​​​‌ large class of queueing‌ systems among which, Whittle‌​‌ networks and Order-Independent (OI)​​ queues. When complemented with​​​‌ a balanced access control‌ mechanism, the quasi-reversibility property‌​‌ of the system is​​ conserved and a simple​​​‌ quasi-product form holds for‌ the stationary distribution 29‌​‌. Besides, this allows​​ to implement simple and​​​‌ efficient algorithms to optimize‌ the access control in‌​‌ function of the system​​ state. Finally, as observed​​​‌ in a few cases‌ in 29, reinforcement‌​‌ learning algorithms of the​​ Policy gradient (RLPG) type​​​‌ appear to be particularly‌ efficient in this context.‌​‌ We are currently working​​ at an extensive analytical​​​‌ study of the performance‌ of these algorithms in‌​‌ a much broader range​​ of systems.

In a​​​‌ second line of work,‌ Pascal Moyal and Thomas‌​‌ Masanet (former PhD student,​​ now teacher) worked in​​​‌ collaboration with Christian Jacquelinet‌ and Benoît Audry (Agence‌​‌ de la Biomédecine -​​ ABM) at the optimization​​​‌ of organ transplant networks.‌ They proposed in 14‌​‌ an allocation policy based​​ on Earliest Simulated Deadline​​​‌ First (ESDF) queueing. Extensive‌ simulations show ESDF performs‌​‌ better than the current​​ Score algorithm (implemented by​​​‌ the ABM at the‌ nationwide scale) in equity‌​‌ across indication classes for​​ liver transplants, especially during​​​‌ organ shortage, while maintaining‌ comparable death rates. These‌​‌ results are promising since​​ ESDF is easier to​​​‌ implement and explain to‌ patients, yet performs better.‌​‌ Current work focuses on​​ providing analytical proofs of​​​‌ ESDF optimality and extending‌ the study to cross-kidney‌​‌ transplants with compatibility constraints​​ on general graphs. This​​​‌ leads to a control‌ problem of dynamic matching‌​‌ models.

7.9 Comparing critical​​ editions of ancient texts​​​‌

Participants: Antoine Lejay,‌ Lionel Lenotre.

Within‌​‌ the Némésis grant from​​ MITI CNRS, we have​​​‌ developed a methodology to‌ compare variants between two‌​‌ critical editions of the​​ same text. The core​​​‌ methodology relies on an‌ ad hoc format to‌​‌ store a text as​​ a sequence of tokens​​​‌ embedding metadata. To overcome‌ the limitations of the‌​‌ XML-TEI encoding, which is​​ classically used for ancient​​​‌ texts, a representation with‌ hypergraphs supersedes a tree‌​‌ based representation in order​​ to account for the​​​‌ overlapping division of the‌ text. The differences were‌​‌ automatically classified. The method​​ was applied to two​​​‌ high-quality digitized versions of‌ critical editions of Aristotle's‌​‌ Politics.

7.10 Geometric​​ features of nested regressions​​​‌ and loss landscape

Participants:‌ Antoine Lejay, Lionel‌​‌ Lenotre, Saïd Toubra​​.

We are studying​​​‌ the effect of nested‌ regression in linear least-squares‌​‌ on the geometry of​​ the loss landscape. Considering​​​‌ the product of two‌ matrices in a linear‌​‌ least-squares regression instead of​​ a single matrix leads​​​‌ to a radically different‌ structure of the loss‌​‌ landscape, with the introduction​​ of many saddle points,​​​‌ as pointed out by‌ Baldi and Hornik in‌​‌ 35. Using tools​​​‌ from geometry and optimization,​ we aim at providing​‌ a better description of​​ the loss landscape and​​​‌ its impact on gradient​ descent algorithms. This work​‌ is motivated by the​​ fact that up to​​​‌ a non-linear transformation, the​ attention mechanism, which is​‌ central in the transformers'​​ architecture, actually performs a​​​‌ nested regression. This work​ then aims at being​‌ applied to provide a​​ better understanding of the​​​‌ mechanisms of Large Language​ Models (LLM) and related​‌ neural networks.

8.1 International​​​‌ initiatives

8.2 International​‌ research visitors

8.3 European‌​‌ initiatives

Participants: Nathan Gillot​​, Freja Nørby,​​​‌ Radu Stoica.

• Title:‌
  HORIZON WIDERA TWINNING EU‌​‌ Project : EXCOSM -​​ Building excellence in the​​​‌ study of galaxies and‌ cosmology at University of‌​‌ Tartu
• Partner Institutions:
   

  • Université​​ de Lorraine
  • Tartu University​​​‌ (Estonia)
  • Leibniz institute for‌ Astrophysics Potsdam (Germany)
  • University‌​‌ of Groningen (Germany)
• Date/Duration:​​
  Octorber 2024-September 2027
• Additionnal​​​‌ info/keywords:
  Radu Stoica is‌ the PI for Université‌​‌ de Lorraine.
• Summary:
  The​​ EXCOSM project enhances galaxy​​​‌ evolution research by combining‌ observational data, simulations, and‌​‌ cosmic web theory to​​ understand how galactic environments​​​‌ influence star formation and‌ mass assembly. Through international‌​‌ collaboration, the University of​​ Tartu will develop advanced​​​‌ methods for modeling the‌ cosmic web, strengthening its‌​‌ research capacity and global​​ visibility in these fundamental​​​‌ cosmological studies.

8.4 National‌ initiatives

Participants: Antoine Lejay‌​‌, Lionel Lenotre,​​ Saïd Toubra.

• Title:​​​‌
  Nouvelles Études en Humanités‌ Numériques (Némésis)
• Partner Institutions:‌​‌
   

  • Inria, France
  • Université de​​ Haute-Alsace
• Date/Duration:
  January 2024-December​​​‌ 2025
• Additionnal info/keywords:
  The‌ PIs are Maria-Teresa Schettino‌​‌ and Antoine Lejay.
• Summary:​​
  This grant (funding: programme​​​‌ Blanc MITI CNRS) supports‌ the interdisciplinary research in‌​‌ the field of Digital​​ Humanities, namely the development​​​‌ of the Palamède software‌ within the Apollon project‌​‌ and the PhD thesis​​ of Saïd Toubra .​​​‌

8.5 Public policy support‌

Participants: Antoine Lejay.‌​‌

• Antoine Lejay worked in​​ a contract with Polyor​​​‌ SAS on the prediction‌ of nitrite in agricultural‌​‌ use, with a grant​​ from the Métropole du​​​‌ Grand Nancy.

9.1 Promoting scientific activities‌​‌

9.2​‌ Teaching - Supervision -​​ Juries - Educational and​​​‌ pedagogical outreach

Pascal Moyal​ and Radu Stoica are​‌ professors. They have full​​ teaching duties with lectures​​​‌ at all the levels​ of the university. Sara​‌ Mazzonetto is assistant professor,​​ who was on partial​​​‌ leave this year. For​ them all, we mention​‌ here only lectures at​​ Master 1 and Master​​​‌ 2 levels as well​ as responsibilities.

• Madalina Deaconu​‌ , Stochastic Modeling,​​ 30h, M2, Master IMSD,​​​‌ Université de Lorraine.
• Madalina​ Deaconu , Monte Carlo​‌ Simulation, 24h, M1,​​ Financial Mathematical Engineering, Université​​​‌ de Lorraine.
• Madalina Deaconu​ , Random Variable simulation​‌, 12h, M1, École​​ des Mines de Nancy,​​​‌ Université de Lorraine.
• Antoine​ Lejay , Simulation des​‌ marchés financiers, 23h,​​ M2, Master PSA, Université​​​‌ de Lorraine.
• Antoine Lejay​ , Financial mathematics,​‌ 18h, M2, Master IMSD,​​ Université de Lorraine.
• Sara​​​‌ Mazzonetto , Probability and​ Statistics, 25h, M1,​‌ Master IMSD and MFA,​​ Université de Lorraine.
• Sara​​​‌ Mazzonetto , Stochastic calculus​ for finance, 16h,​‌ M2, Master IMSD, Université​​ de Lorraine.
• Pascal Moyal​​​‌ is Head of the​ Working Group Master IA​‌ of Université de Lorraine.​​
• Pascal Moyal , Financial​​​‌ mathematics, 25h, M2,​ Master IMSD, Université de​‌ Lorraine.
• Pascal Moyal ,​​ Stochastic calculus for finance​​​‌, 9h, M2, Master​ IMSD, Université de Lorraine.​‌
• Pascal Moyal , Reinforcement​​ learning, 12h, M2,​​​‌ Master IMSD, Université de​ Lorraine.
• Pascal Moyal ,​‌ Stochastic modeling, 12h,​​ M2, Master IMSD, Université​​​‌ de Lorraine.
• Pascal Moyal​ , Random graphs and​‌ their applications, 30h,​​ M2, Master MFA, Université​​​‌ de Lorraine.
• Pascal Moyal​ , Graph theory and​‌ Neural networks, 30h,​​ M1, Master Math., Université​​​‌ de Lorraine.
• Pascal Moyal​ , Stochastic calculus,​‌ 24h, Master level, Telecom​​ Paristech.
• Pascal Moyal ,​​​‌ Stochastic networks, 17h30,​ Master level, Mastère Parisien​‌ de Recherche Opérationnelle,​​ CNAM.
• Pascal Moyal ,​​​‌ Operations research, Master​ level, Mastère TET,​‌ École des Ponts et​​ Chaussées.
• Radu Stoica is​​​‌ the head of the​ Master M2 IMSD Ingénierie​‌ Mathématique et Science des​​ Données, Université de​​​‌ Lorraine.
• Radu Stoica ,​ Simulation and Inference via​‌ Monte Carlo Methods,​​ 28h, M1, Master IMSD,​​​‌ Université de Lorraine.
• Radu​ Stoica , Spatial Statistics​‌ and Bayesian Inference,​​ 36h, M2, Master IMSD,​​​‌ Université de Lorraine.

9.3 Popularization

10.1‌ Major publications

• 1 article‌​‌L.Lucian Beznea,​​ M.Madalina Deaconu and​​​‌ O.Oana Lupascu.‌ Stochastic equation of fragmentation‌​‌ and branching processes related​​ to avalanches.Journal​​​‌ of Statistical Physics162‌4February 2016,‌​‌ 824-841HALDOI
• 2​​ articleM.Madalina Deaconu​​​‌ and S.Samuel Herrmann‌. Initial-boundary value problem‌​‌ for the heat equation​​ - A stochastic algorithm​​​‌.Annals of Applied‌ Probability2832018‌​‌, 1943-1976HALDOI​​
• 3 articleM.Madalina​​​‌ Deaconu and A.Antoine‌ Lejay. Probabilistic representations‌​‌ of fragmentation equations.​​Probability Surveys202023​​​‌, 226-290HALDOI‌
• 4 articleA.Antoine‌​‌ Lejay. Constructing general​​ rough differential equations through​​​‌ flow approximations.Electronic‌ Journal of Probability27‌​‌2021, 1-24HAL​​DOI
• 5 articleA.​​​‌Antoine Lejay and S.‌Sara Mazzonetto. Maximum‌​‌ likelihood estimator for skew​​ Brownian motion: the convergence​​​‌ rate.Scandinavian Journal‌ of StatisticsFebruary 2023‌​‌HALDOI
• 6 article​​S.Sara Mazzonetto and​​​‌ B.Benoît Nieto.‌ Parameters estimation of a‌​‌ Threshold CKLS process from​​ continuous and discrete observations​​​‌.Scandinavian Journal of‌ Statistics5242025‌​‌, 1670-1707HALDOI​​​‌
• 7 miscS.Sara​ Mazzonetto. Rates of​‌ convergence to the local​​ time of Oscillating and​​​‌ Skew Brownian Motions.​October 2021HAL
• 8​‌ articleP.Pascal Moyal​​, A.Ana Bušić​​​‌ and J.Jean Mairesse​. A product form​‌ for the general stochastic​​ matching model.Journal​​​‌ of Applied Probability58​2June 2021,​‌ 449-468HALDOI
• 9​​ articleY.Youssef Rahme​​​‌ and P.Pascal Moyal​. A stochastic matching​‌ model on hypergraphs.​​Advances in Applied Probability​​​‌5342021,​ 951-980HALDOI
• 10​‌ inproceedingsC.Christophe Reype​​, A.Antonin Richard​​​‌, M.Madalina Deaconu​ and R. S.Radu​‌ S. Stoica. Bayesian​​ statistical analysis of hydrogeochemical​​​‌ data using point processes:​ a new tool for​‌ source detection in multicomponent​​ fluid mixtures.RING​​​‌ Meeting 2020Nancy, France​September 2020HAL
• 11​‌ articleR.Radu Stoica​​, M.Madalina Deaconu​​​‌, A.Anne Philippe​ and L.Lluis Hurtado-Gil​‌. Shadow Simulated Annealing:​​ A new algorithm for​​​‌ approximate Bayesian inference of​ Gibbs point processes.​‌Spatial StatisticsApril 2021​​HALDOI

10.2 Publications​​​‌ of the year

10.3 Cited publications

• 34​ unpublishedA.Alexis Anagnostakis​‌ and S.Sara Mazzonetto​​. On the number​​​‌ of crossings and bouncings​ of a diffusion at​‌ a sticky threshold.​​October 2024, working​​​‌ paper or preprintHAL​back to text
• 35​‌ articleP.Pierre Baldi​​ and K.Kurt Hornik​​​‌. Neural networks and​ principal component analysis: Learning​‌ from examples without local​​ minima.Neural Networks​​​‌21January 1989​, 53–58URL: http://dx.doi.org/10.1016/0893-6080(89)90014-2​‌DOIback to text​​
• 36 articleS.Sara​​​‌ Mazzonetto and P.Paolo​ Pigato. Drift estimation​‌ of the threshold Ornstein-Uhlenbeck​​ process from continuous and​​​‌ discrete observations.Statistica​ Sinica3412024​‌, 313-336HALDOI​​back to text
• 37​​​‌ unpublishedS.Sara Mazzonetto​ and P.Paolo Pigato​‌. Estimation of parameters​​ and local times in​​​‌ a discretely observed threshold​ diffusion model.March​‌ 2024, working paper​​ or preprintHALback​​​‌ to text