2025​Activity reportProject-TeamIDEFIX​‌

5.1.1 ECIP

• Name:​​
  Eddy Current Imaging for​​​‌ Pipes
• Keywords:
  Inverse problem,​ Partial differential equation, HPC,​‌ Domain decomposition
• Functional Description:​​
  This software identifies deposit​​​‌ on pipes from measurements​ of eddy current probes.​‌ It is based on​​ finite elements and domain​​​‌ decomposition through the softwares​ HPDDM, PETSc and FreeFEM,​‌ for the resolution of​​ the PDE model of​​​‌ the eddy current measurements.​ It uses an iterative​‌ algorithm to identify the​​ deposit properties.
• Contact:
  Lorenzo​​​‌ Audibert
• Partner:
  Edf

5.1.2​ SpinDoctor

• Name:
  SpinDoctor Diffusion​‌ MRI Simulation Toolbox
• Keywords:​​
  MRI, Simulation, Finite element​​​‌ modelling
• Functional Description:

  SpinDoctor​ can be used

  1.​‌ to solve the Bloch-Torrey​​ PDE to obtain the​​​‌ dMRI signal (the toolbox​ provides a way of​‌ robustly fitting the dMRI​​ signal to obtain the​​​‌ fitted Apparent Diffusion Coefficient​ (ADC)), 2. to solve​‌ the diffusion equation of​​ the H-ADC model to​​​‌ obtain the ADC, 3.​ a short-time approximation formula​‌ for the ADC is​​ also included in the​​​‌ toolbox for comparison with​ the simulated ADC.

• URL:​‌
  https://­github.­com/­SpinDoctorMRI/
• Contact:
  Jing Rebecca​​ Li

5.1.3 CASTOR

• Keyword:​​​‌
  C++
• Functional Description:

  The​ objective of the castor​‌ library is to propose​​ high-level semantics, inspired by​​​‌ the Matlab language, allowing​ fast software prototyping in​‌ a low-level compiled language.​​ It is nothing more​​​‌ than a matrix management​ layer using the tools​‌ of the standard C++​​ library, in different storage​​​‌ formats (full, sparse and​ hierarchical). Indeed, the use​‌ of IDEs 1 such​​ as Xcode, Visual studio,​​​‌ Eclipse, etc. allows today​ to execute compiled code​‌ (C, C++, fortran, etc.)​​ with the same flexibility​​​‌ as interpreted languages (Matlab,​ Python, Julia, etc.).

  A​‌ header-only template library for​​ matrix management has been​​​‌ developed based on the​ standard C++ library, notably​‌ the std::vector class. Many​​ tools and algorithms are​​​‌ provided to simplify the​ development of scientific computing​‌ programs. Particular attention has​​ been paid to semantics,​​​‌ for a simplicity of​ use “à la matlab”,​‌ but written in C++.​​ This high-level semantic/low-level language​​​‌ coupling makes it possible​ to gain efficiency in​‌ the prototyping phase, while​​ ensuring performance for applications.​​​‌ In addition, direct access​ to data allows users​‌ to optimize the most​​ critical parts of their​​​‌ code in native C++.​ Finally, complete documentation is​‌ available, as well as​​ continuous integration unit tests.​​​‌ All of this makes​ it possible to meet​‌ the needs of teaching,​​ academic issues and industrial​​​‌ applications at the same​ time.

  The castor library​‌ provides tools to :​​

  create and manipulate dense,​​​‌ sparse and hierarchical matrices​ make linear algebra computations​‌ based on optimized BLAS​​ library make graphical representations​​ based on VTK library​​​‌ These tools are used‌ by applicative projects :‌​‌

  finite and boundary element​​ method using Galerkin approximation​​​‌ analytical solutions for scattering‌ problems

• URL:
  https://­leprojetcastor.­gitlab.­labos.­polytechnique.­fr/­castor/­#
• Contact:‌​‌
  Matthieu Aussal

5.1.4 lostinmsh​​

• Keywords:
  Mathematics, Mesh generation​​​‌
• Functional Description:
  The Python‌ toolbox lostinmsh (LOcally STructured‌​‌ polygonal INterface MeSH), is​​ a package using GMSH​​​‌ to construct locally structured‌ triangular meshes of polygons‌​‌ which are useful for​​ sign changing PDE problem.​​​‌
• URL:
  https://­zmoitier.­github.­io/­lostinmsh/
• Contact:
  Zois‌ Moitier

5.1.5 HAdaptiveIntegration.jl

• Keywords:‌​‌
  Mathematics, Numerical analysis, Scientific​​ computing
• Functional Description:
  Julia​​​‌ package designed for numerical‌ integration over multidimensional domains.‌​‌
• URL:
  https://­zmoitier.­github.­io/­HAdaptiveIntegration.­jl/­stable/
• Contact:
  Zois​​ Moitier

5.1.6 Reduced Basis​​​‌ Methods Documentation

• Keywords:
  Reduced‌ Basis Methods, Numerical simulations,‌​‌ Finite element modelling
• Functional​​ Description:
  This website provides​​​‌ a basic introduction to‌ Reduced Basis Methods (RBM).‌​‌ They aim at reducing​​ the runtimes of classical​​​‌ methods of resolution (e.g.‌ finite elements method) for‌​‌ parameterized partial differential equations​​ when they have to​​​‌ be solved for many‌ different parameter values. They‌​‌ have many applications arising​​ from engineering and applied​​​‌ sciences, such as real-time‌ simulation or calibration problems.‌​‌ For each RBM (POD-Galerkin,​​ PODI, NIRB two-grid, EIM,​​​‌ PBDW), a short description‌ with links to several‌​‌ articles is presented, and​​ a simple application in​​​‌ a Python notebook and‌ links to other computational‌​‌ langages (such as Fenics/Feel++/FreeFem++)​​ are provided.
• Contact:
  Elise​​​‌ Grosjean

6.1.1 Analysis​​ of Sampling methods with​​​‌ and without linearization

L.Audibert,‌ S. Meng

Sampling methods‌​‌ were designed to identify​​ the support of an​​​‌ obstacle from multistatic measurements,‌ with theoretical guarantees that‌​‌ do not rely on​​ linearizing the scattering problem.​​​‌ However, the indicator functions‌ they produce remain, to‌​‌ some extent, poorly understood.​​ In an initial study,​​​‌ we derived computable quantities‌ that shed light on‌​‌ the behavior of these​​ indicator functions.

To push​​​‌ this understanding further, we‌ turned to the Born‌​‌ linearization, under which the​​ Linear Sampling Method (LSM)​​​‌ indicator can be interpreted‌ as a non-uniform average‌​‌ of the reciprocal of​​ the contrast. In doing​​​‌ so, we uncovered for‌ the Born approximation an‌​‌ unexpected and unphysical resampling​​ and factorization of the​​​‌ far-field operator, which enables‌ the combination of data‌​‌ from multiple frequencies. This​​ reformulation reduces the problem​​​‌ to the analysis of‌ a restricted Fourier operator.‌​‌

This operator naturally leads​​ to the use of​​​‌ Prolate Spheroidal Wave Functions‌ (PSWFs), well known in‌​‌ harmonic analysis for their​​ optimal concentration properties. We​​​‌ then investigate the usefulness‌ of this basis for‌​‌ linearized inverse scattering, assessing​​ its potential for improved​​​‌ reconstruction and understanding of‌ sampling-type indicators.

6.1.2 Fast‌​‌ Imaging of Local Perturbations​​ in a Unknown Bi-Periodic​​​‌ Layered Medium

H. Haddar,‌ N. Jenhani

We consider‌​‌ a nondestructive testing problem​​ involving an infinite periodic​​​‌ penetrable layer probed by‌ acoustic waves. This problem‌​‌ is of growing interest,​​ as periodic structures play​​​‌ a central role in‌ many modern technological applications‌​‌ across (bio)engineering and materials​​​‌ science. In many advanced​ devices, however, the periodic​‌ architecture may be highly​​ complex or difficult to​​​‌ model mathematically. As a​ result, evaluating its Green’s​‌ function, an essential ingredient​​ in numerous imaging techniques,​​​‌ can become computationally expensive​ or even infeasible.

At​‌ the same time, when​​ analyzing flows or defects​​​‌ in such complex media,​ fully reconstructing both the​‌ periodic structure and the​​ localized anomalies is often​​​‌ unrealistic. In earlier work,​ we proposed an approach​‌ that provides a criterion​​ for identifying the support​​​‌ of local anomalies without​ requiring explicit knowledge or​‌ reconstruction of the healthy​​ periodic background.

To address​​​‌ more general scenarios related​ to this method, one​‌ encounters the need to​​ analyze an interior transmission​​​‌ problem posed in an​ unbounded domain. This setting​‌ renders classical approaches inapplicable,​​ as the Rellich compactness​​​‌ theorem cannot be used​ in unbounded geometries. In​‌ 7, we introduced​​ a new approach based​​​‌ on the analysis of​ a semi-discretized reformulation of​‌ the problem using the​​ Floquet–Bloch transform.

6.2.1​​ Examples of non-scattering inhomogeneities​​​‌

L. Chesnel, H. Haddar,​ H. Li, J. Xiao​‌

We consider the scattering​​ of waves by a​​​‌ penetrable inclusion embedded in​ some reference medium. We​‌ exhibit examples of materials​​ and geometries for which​​​‌ non-scattering frequencies exist, i.e.,​ for which at some​‌ frequencies there are incident​​ fields which produce null​​​‌ scattered fields outside of​ the inhomogeneity. We show​‌ in particular that certain​​ domains with corners or​​​‌ even cusps can support​ non-scattering frequencies. We relate​‌ the latter, for some​​ inclusions, to resonance frequencies​​​‌ for Dirichlet or Neumann​ cavities. We also find​‌ situations where incident non-scattering​​ fields solve the Helmholtz​​​‌ equation in a neighbourhood​ of the inhomogeneity and​‌ not in the whole​​ space. In relation with​​​‌ invisibility, we give examples​ of inclusions of anisotropic​‌ materials which are non-scattering​​ for all real frequencies.​​​‌ We prove that corresponding​ material indices must have​‌ a special structure on​​ the boundary 4.​​​‌

6.2.2 Averaged Steklov Eigenvalues,​ Inside OutsideDuality and Application​‌ to Inverse Scattering

L.​​ Audibert, Houssem Haddar and​​​‌ Fabien Pourre

We introduce​ a new family of​‌ artificial backgrounds corresponding to​​ averaged impedance boundary conditions​​​‌ formulated in an abstract​ framework. These backgrounds are​‌ used to define a​​ finite number of averaged​​​‌ Steklov eigenvalues, which are​ associated with inverse scattering​‌ problems from inhomogeneous media.​​ We prove that these​​​‌ special eigenvalues can be​ determined from full-aperture, fixed-frequency​‌ far-fields using the inside-outside​​ duality method. We then​​​‌ show and numerically demonstrate​ how this method can​‌ be used to reconstruct​​ averaged values of the​​​‌ refractive index. 2

6.3.1 Perfect transmission in​ periodic waveguides with localized​‌ defects

L. Chesnel, T.​​ Creuset, Z. Moitier

In​​​‌ this work, we study​ wave propagation in periodic​‌ waveguides with localised defects.​​ Generally speaking, in such​​​‌ structures, for certain bands​ of frequencies, waves can​‌ propagate, leading to reflection​​ and transmission phenomena. Our​​ goal is to identify​​​‌ situations, by varying the‌ frequency and/or the perturbation‌​‌ in the reference periodic​​ medium, where the energy​​​‌ of an incident wave‌ is perfectly transmitted. In‌​‌ the internship of T.​​ Creuset, we considered 1D​​​‌ periodic materials for which‌ dispersion curves can be‌​‌ computed explicitly. Then we​​ investigated both theoretically and​​​‌ numerically three different techniques,‌ inspired by the case‌​‌ where the reference medium​​ is homogeneous, to reach​​​‌ perfect invisibility.

6.3.2 Eigenvalue‌ falls in thin broken‌​‌ quantum strips

L. Chesnel,​​ S.A. Nazarov

We are​​​‌ interesting in the spectrum‌ of the Dirichlet Laplacian‌​‌ in thin broken strips​​ with angle $\alpha$.​​​‌ Playing with symmetries, this‌ leads us to investigate‌​‌ spectral problems for the​​ Laplace operator with mixed​​​‌ boundary conditions in thin‌ trapezoids characterized by a‌​‌ parameter $\epsilon$ small. We​​ give an asymptotic expansion​​​‌ of the first eigenvalues‌ and corresponding eigenfunctions as‌​‌ $\epsilon$ tends to zero.​​ The new point in​​​‌ this work is to‌ study the dependence with‌​‌ respect to $\alpha$.​​ We show that for​​​‌ a small fixed $\mathrm{\epsilon ‌}>0$, at‌​‌ certain particular angles ${\mathrm{\alpha }}_k^{☆}$, $\mathrm{k‌}=0,\mathrm{1‌},\cdots$, that‌​‌ we characterize, an eigenvalue​​ dives, i.e. moves down​​​‌ rapidly, below the normalized‌ threshold ${\pi }^2/‌‌{\epsilon }^2$ as $\mathrm{\alpha }>0$ increases. We​​​‌ describe the way the‌ eigenvalue dives below ${\mathrm{\pi ‌‌}}^2/{\epsilon }^{\mathrm{2}}$ and prove that the​​​‌ phenomenon is milder at‌ ${\alpha }_0^{☆}=‌‌0$ than at ${\mathrm{\alpha }}_k^{☆}$ for $\mathrm{k‌}\ge 1$. 16‌

6.3.3 On the breathing‌​‌ of spectral bands in​​ periodic quantum waveguides with​​​‌ inflating resonators

L. Chesnel,‌ S.A. Nazarov

We are‌​‌ interested in the lower​​ part of the spectrum​​​‌ of the Dirichlet Laplacian‌ $A^{\epsilon }$ in a‌​‌ thin waveguide ${\Pi }^{\mathrm{\epsilon }}$ obtained by repeating periodically​​​‌ a pattern, itself constructed‌ by scaling an inner‌​‌ field geometry $\Omega$ by​​ a small factor $\mathrm{\epsilon ‌}>0$. The‌ Floquet-Bloch theory ensures that‌​‌ the spectrum of ${\mathrm{A}}^{\epsilon }$ has a band-gap​​​‌ structure. Due to the‌ Dirichlet boundary conditions, these‌​‌ bands all move to​​ $+\infty$ as $\mathrm{O‌}\left({\epsilon }^{-\mathrm{2‌}}\right)$ when $\epsilon \to ‌‌0^{+}$. Concerning​​ their widths, applying techniques​​​‌ of dimension reduction, we‌ show that the results‌​‌ depend on the dimension​​ of the so-called space​​​‌ of almost standing waves‌ in $\Omega$ that we‌​‌ denote by ${\mathrm{X}}_{†}$. Generically, i.e. for​​​‌ most $\Omega$, there‌ holds ${\mathrm{X}}_{†}=‌‌\left\{0\right\}$ and​​ the lower part of​​​‌ the spectrum of ${\mathrm{A‌}}^{\epsilon }$ is very sparse,‌​‌ made of bands of​​ length at most $\mathrm{O‌}\left(\epsilon \right)$ as‌ $\epsilon \to 0^{+‌‌}$. For certain $\mathrm{\Omega }$ however, we have $\mathrm{dim‌}{\mathrm{X}}_{†}=\mathrm{1‌}$ and then there are‌​‌ bands of length $\mathrm{O}\left(1\right)$ which​​​‌ allow for wave propagation‌ in ${\Pi }^{\epsilon }$.‌​‌ The main originality of​​ this work lies in​​​‌ the study of the‌ behaviour of the spectral‌​‌ bands when perturbing $\mathrm{\Omega ‌}$ around a particular ${\mathrm{\Omega }}_{☆}$ where $\dim {\mathrm{X‌}}_{†}=1$.​​ We show a breathing​​​‌ phenomenon for the spectrum​ of $A^{\epsilon }$:​‌ when inflating $\Omega$ around​​ ${\Omega }_{☆}$, the​​​‌ spectral bands rapidly expand​ before shrinking. In the​‌ process, a band dives​​ below the normalized threshold​​​‌ ${\pi }^2/{\mathrm{\epsilon }}^2$, stops breathing​‌ and becomes extremely short​​ as $\Omega$ continues to​​​‌ inflate. 5

6.3.4 Construction​ of transparent boundary conditions​‌ in electromagnetic waveguides

Anne-Sophie​​ Bonnet-Ben Dhia, Lucas Chesnel,​​​‌ Sonia Fliss, Aurélien Parigaux​

In the PhD of​‌ A. Parigaux, we studied​​ the propagation of electromagnetic​​​‌ waves in unbounded waveguides.​ The objective was to​‌ obtain transparent boundary conditions​​ to bound in an​​​‌ appropriate way the computational​ domain. The case of​‌ heterogeneous waveguides, for which​​ the electromagnetic coefficients vary​​​‌ in the cross-section, raises​ complex issues that motivated​‌ this work. In particular,​​ determining the modes at​​​‌ a fixed frequency leads​ to consider a non​‌ self-adjoint problem and so-called​​ "backward modes", for which​​​‌ phase and group velocities​ have different signs, can​‌ exist. In our study,​​ we proposed and validated​​​‌ numerically two types of​ transparent boundary conditions based​‌ respectively on the use​​ of an Electric-to-Magnetic (EtM)​​​‌ operator and a Currents-to-Magnetic​ (CtM) operator. These allow​‌ one to connect the​​ finite element representation of​​​‌ the approximation with a​ modal decomposition in the​‌ unperturbed regions of the​​ waveguide. 9

6.3.5 Trapped​​​‌ modes in electromagnetic waveguides​

Anne-Sophie Bonnet-Ben Dhia, Lucas​‌ Chesnel, Sonia Fliss

We​​ consider the Maxwell's equations​​​‌ with perfect electric conductor​ boundary conditions in three-dimensional​‌ unbounded domains which are​​ the union of a​​​‌ bounded resonator and one​ or several semi-infinite waveguides.​‌ We are interested in​​ the existence of electromagnetic​​​‌ trapped modes, i.e.${\mathrm{L}}^2$ solutions of the​‌ problem without source term.​​ These trapped modes are​​​‌ associated to eigenvalues of​ the Maxwell's operator, that​‌ can be either below​​ the essential spectrum or​​​‌ embedded in it. First​ for homogeneous waveguides, we​‌ presented different families of​​ geometries for which we​​​‌ can prove the existence​ of eigenvalues. Then we​‌ exhibited certain non homogeneous​​ waveguides with local perturbations​​​‌ of the dielectric constants​ that support trapped modes.​‌ Let us mention that​​ some of the mechanisms​​​‌ we proposed are very​ specific to Maxwell's equations​‌ and have no equivalent​​ for the scalar Dirichlet​​​‌ or Neumann Laplacians. 14​

6.4.1 SpinDoctor-IVIM: A​ virtual imaging framework for​‌ intravoxel incoherent motion MRI​​

Mojtaba Lashgari, Zheyi Yang,​​​‌ Miguel O. Bernabeu, Jing-Rebecca​ Li, Alejandro F. Frangi​‌

Intravoxel incoherent motion (IVIM)​​ imaging is increasingly recognised​​​‌ as an important tool​ in clinical MRI, where​‌ tissue perfusion and diffusion​​ information can aid disease​​​‌ diagnosis, monitoring of patient​ recovery, and treatment outcome​‌ assessment. Currently, the discovery​​ of biomarkers based on​​​‌ IVIM imaging, similar to​ other medical imaging modalities,​‌ is dependent on long​​ preclinical and clinical validation​​​‌ pathways to link observable​ markers derived from images​‌ with the underlying pathophysiological​​ mechanisms. To speed up​​ this process, virtual IVIM​​​‌ imaging is proposed. This‌ approach provides an efficient‌​‌ virtual imaging tool to​​ design, evaluate, and optimise​​​‌ novel approaches for IVIM‌ imaging. In this work,‌​‌ virtual IVIM imaging is​​ developed through a new​​​‌ finite element solver, SpinDoctor-IVIM,‌ which extends SpinDoctor, a‌​‌ diffusion MRI simulation toolbox.​​ SpinDoctor-IVIM simulates IVIM imaging​​​‌ signals by solving the‌ generalised Bloch–Torrey partial differential‌​‌ equation. The input velocity​​ to SpinDoctor-IVIM is computed​​​‌ using HemeLB, an established‌ Lattice Boltzmann blood flow‌​‌ simulator. Contrary to previous​​ approaches, SpinDoctor-IVIM accounts for​​​‌ volumetric microvasculature during blood‌ flow simulations, incorporates diffusion‌​‌ phenomena in the intravascular​​ space, and accounts for​​​‌ the permeability between the‌ intravascular and extravascular spaces.‌​‌ The above-mentioned features of​​ the proposed framework are​​​‌ illustrated with simulations on‌ a realistic microvasculature model.‌​‌

6.4.2 Alpha_Mesh_Swc: automatic​​ and robust surface mesh​​​‌ generation from the skeleton‌ description of brain cells‌​‌

Alex McSweeney-Davis, Chengran Fang,​​ Emmanuel Caruyer, Anne Kerbrat,​​​‌ Jing-Rebecca Li

In recent‌ years, there has been‌​‌ a significant increase in​​ publicly available skeleton descriptions​​​‌ of real brain cells‌ from laboratories all over‌​‌ the world. In theory,​​ this should make it​​​‌ possible to perform large‌ scale realistic simulations on‌​‌ brain cells. However, currently​​ there is still a​​​‌ gap between the skeleton‌ descriptions and high quality‌​‌ simulation-ready surface and volume​​ meshes of brain cells.​​​‌

We propose and implement‌ a tool called Alpha_Mesh_Swc‌​‌ to generate automatically and​​ efficiently triangular surface meshes​​​‌ that are optimized for‌ finite elements simulations. We‌​‌ use an Alpha Wrapping​​ method with an offset​​​‌ parameter on component surface‌ meshes to efficiently generate‌​‌ a global watertight mesh.​​ Then mesh simplification and​​​‌ re-meshing are used to‌ produce an optimal surface‌​‌ mesh. Our methodology limits​​ the number of surface​​​‌ triangles while preserving geometrical‌ accuracy, permits cutting and‌​‌ gluing of cell components,​​ is robust to imperfect​​​‌ skeleton descriptions, and allows‌ mixed cell descriptions (surface‌​‌ meshes combined with skeletons).​​

We compared the robustness,​​​‌ performance and accuracy of‌ Alpha_Mesh_Swc against existing tools‌​‌ and found significant improvement​​ in terms of mesh​​​‌ accuracy. We show, on‌ average, we can generate‌​‌ fully automatically a brain​​ cell (neurons or glia)​​​‌ surface mesh in a‌ couple of minutes on‌​‌ a laptop computer resulting​​ in a simplified surface​​​‌ mesh with only around‌ 10k nodes. The resulting‌​‌ meshes were used to​​ perform diffusion MRI simulations​​​‌ in neurons and microglia.‌ The code and a‌​‌ number of sample brain​​ cell surface meshes have​​​‌ been made publicly available.‌

6.5.1​​​‌ Discrete FEM-BEM coupling with‌ the Generalized Optimized Schwarz‌​‌ Method

A. Boisneault, M.​​ Bonazzoli, X. Claeys, P.​​​‌ Marchand

We have developed‌ a non-overlapping Domain Decomposition‌​‌ (DD) approach to the​​ solution of acoustic wave​​​‌ propagation boundary value problems‌ based on the Helmholtz‌​‌ equation, on both bounded​​ and unbounded domains. This​​​‌ DD solver, called Generalized‌ Optimized Schwarz Method (GOSM),‌​‌ is a substructuring method,​​​‌ that is, the unknowns​ of an iteration are​‌ associated with the subdomains​​ interfaces. We extend the​​​‌ existing continuous analysis to​ a fully discrete setting.​‌ We do not consider​​ only a specific set​​​‌ of boundary conditions, but​ a whole class including,​‌ e.g., Dirichlet, Neumann, and​​ Robin conditions. Our analysis​​​‌ also covers interface conditions​ corresponding to a Finite​‌ Element Method - Boundary​​ Element Method (FEM-BEM) coupling.​​​‌ In particular, we focus​ on three classical FEM-BEM​‌ couplings, namely the Costabel,​​ Johnson-Nédélec and Bielak-MacCamy couplings.​​​‌ As a remarkable outcome,​ the present contribution yields​‌ well-posed substructured formulations of​​ these classical FEM-BEM couplings​​​‌ for wavenumbers different from​ classical spurious resonances. We​‌ also establish an explicit​​ relation between the dimensions​​​‌ of the kernels of​ the initial variational formulation,​‌ the local problems and​​ the substructured formulation. This​​​‌ relation especially holds for​ any wavenumber for the​‌ substructured formulation of Costabel​​ FEM-BEM coupling, which allows​​​‌ us to prove that​ the latter formulation is​‌ well-posed even at spurious​​ resonances. Besides, we introduce​​​‌ a systematically geometrically convergent​ iterative method for the​‌ Costabel FEM-BEM coupling, with​​ estimates on the convergence​​​‌ speed. An article is​ under preparation.

6.5.2 Spurious​‌ resonances for substructured FEM-BEM​​ coupling

A. Boisneault, M.​​​‌ Bonazzoli, X. Claeys, P.​ Marchand

We are interested​‌ in time-harmonic acoustic scattering​​ by an impenetrable obstacle​​​‌ in a medium where​ the wavenumber is constant​‌ in an exterior unbounded​​ subdomain and is possibly​​​‌ heterogeneous in a bounded​ subdomain. We consider our​‌ new substructured FEM-BEM formulation,​​ called Generalized Optimized Schwarz​​​‌ Method (GOSM), presented in​ the previous subsection. Unfortunately,​‌ it is well known​​ that, even when the​​​‌ initial boundary value problem​ is well-posed, the variational​‌ formulation of classical FEM-BEM​​ couplings can be ill-posed​​​‌ for certain wavenumbers, called​ spurious resonances. Here, we​‌ focus on the Johnson-Nédélec​​ and Costabel couplings and​​​‌ show that the GOSM​ derived from both is​‌ not immune to that​​ issue. In particular, we​​​‌ give an explicit expression​ of the kernel of​‌ the local operator associated​​ with the interface between​​​‌ the FEM and BEM​ subdomains. That kernel and​‌ the one of classical​​ FEM-BEM couplings are simultaneously​​​‌ non-trivial. A proceedings paper​ has been submitted 12​‌.

6.5.3 On the​​ unmapped tent pitching for​​​‌ the heterogeneous wave equation​

M. Bonazzoli, G. Ciaramella,​‌ I. Mazzieri

The Unmapped​​ Tent Pitching (UTP) algorithm​​​‌ is a space-time domain​ decomposition method for the​‌ parallel solution of hyperbolic​​ problems. It was originally​​​‌ introduced for the homogeneous​ one-dimensional wave equation in​‌ [Ciaramella, Gander, Mazzieri, 2024].​​ UTP is inspired by​​​‌ the Mapped Tent Pitching​ (MTP) algorithm [Gopalakrishnan, Schöberl,​‌ Wintersteiger, 2017], which constructs​​ the solution by iteratively​​​‌ building polytopal space-time subdomains,​ referred to as tents.​‌ In MTP, each physical​​ tent is mapped onto​​​‌ a space-time rectangle, where​ local problems are solved​‌ before being mapped back​​ to the original domain.​​​‌ In contrast, UTP avoids​ the nonlinear and potentially​‌ singular mapping step by​​ computing the solution directly​​​‌ on a physical space-time​ rectangle that contains the​‌ tent, at the expense​​ of redundant computations in​​ the region outside the​​​‌ tent. In this work,‌ we investigate several strategies‌​‌ to extend UTP to​​ heterogeneous media, where the​​​‌ wave propagation speed is‌ piecewise constant over two‌​‌ subregions of the domain.​​ Among the considered approaches,​​​‌ the most efficient in‌ terms of computational time‌​‌ is the one employing​​ space-time subdomains with identical​​​‌ spatial and temporal dimensions‌ in both regions, determined‌​‌ by the maximum propagation​​ speed. A proceedings paper​​​‌ has been submitted 13‌.

6.5.4 Convergence rates‌​‌ of curved boundary element​​ methods for the 3D​​​‌ Laplace and Helmholtz equations‌

L. Faria, P. Marchand,‌​‌ H. Montanelli

We establish​​ improved convergence rates for​​​‌ curved boundary element methods‌ applied to the threedimensional‌​‌ (3D) Laplace and Helmholtz​​ equations with smooth geometry​​​‌ and data. Our analysis‌ relies on a precise‌​‌ analysis of the consistency​​ errors introduced by the​​​‌ perturbed bilinear and sesquilinear‌ forms. We illustrate our‌​‌ results with numerical experiments​​ in 3D based on​​​‌ basis functions and curved‌ triangular elements up to‌​‌ order four 17.​​

6.5.5 Nonlocal vector calculus​​​‌ on the sphere

H.‌ Montanelli, M. Slevinsky, Q.‌​‌ Du

We introduce a​​ nonlocal vector calculus on​​​‌ the unit two-sphere using‌ weakly singular integral operators.‌​‌ Within this framework, the​​ operators are diagonalizable in​​​‌ terms of scalar and‌ vector spherical harmonics, a‌​‌ property that facilitates the​​ proof of a nonlocal​​​‌ Stokes theorem. This constitutes‌ the first instance of‌​‌ such a theorem on​​ a curved surface. Furthermore,​​​‌ our analysis demonstrates the‌ strong convergence of these‌​‌ nonlocal operators to the​​ classical differential operators of​​​‌ vector calculus as the‌ interaction range tends to‌​‌ zero 18.

6.5.6​​ High-order numerical integration on​​​‌ self-affine sets

P. Joly,‌ M. Kachanovska, Z. Moitier‌​‌

We construct an interpolatory​​ high-order cubature rule to​​​‌ compute integrals of smooth‌ functions over self-affine sets‌​‌ with respect to an​​ invariant measure. The main​​​‌ difficulty is the computation‌ of the cubature weights,‌​‌ which we characterize algebraically,​​ by exploiting a self-similarity​​​‌ property of the integral.‌ We propose an $\mathrm{h‌‌}$-version and a $\mathrm{p}$-version of the cubature,​​​‌ present an error analysis‌ and conduct numerical experiments.‌​‌

6.5.7 Cell seeding dynamics​​ in a porous scaffold​​​‌ material designed for meniscus‌ tissue regeneration

H. Jäger,‌​‌ E. Grosjean, S. Plunder,​​ C. Redenbach, A. Keilmann​​​‌ , B. Simeon, C.‌ Surulescu

We study the‌​‌ dynamics of a seeding​​ experiment where a fibrous​​​‌ scaffold material is colonized‌ by two types of‌​‌ cell populations. The specific​​ application that we have​​​‌ in mind is related‌ to the idea of‌​‌ meniscus tissue regeneration. In​​ order to support the​​​‌ development of a promising‌ replacement material, we discuss‌​‌ certain rate equations for​​ the densities of human​​​‌ mesenchymal stem cells and‌ chondrocytes and for the‌​‌ production of collagen-containing extracellular​​ matrix. For qualitative studies,​​​‌ we start with a‌ system of ordinary differential‌​‌ equations and refine then​​ the model to include​​​‌ spatial effects of the‌ underlying nonwoven scaffold structure.‌​‌ Numerical experiments as well​​ as a complete set​​​‌ of parameters for future‌ benchmarking are provided.

6.5.8‌​‌ The non-intrusive reduced basis​​​‌ two-grid method applied to​ sensitivity analysis

E. Grosjean,​‌ B. Simeon

This paper​​ deals with the derivation​​​‌ of Non-Intrusive Reduced Basis​ (NIRB) techniques for sensitivity​‌ analysis, more specifically the​​ direct and adjoint state​​​‌ methods. For highly complex​ parametric problems, these two​‌ approaches may become too​​ costly ans thus Reduced​​​‌ Basis Methods (RBMs) may​ be a viable option.​‌ We propose new NIRB​​ two-grid algorithms for both​​​‌ the direct and adjoint​ state methods in the​‌ context of parabolic equations.​​ The NIRB two-grid method​​​‌ uses the HF code​ solely as a “black-box”,​‌ requiring no code modification.​​ Like other RBMs, it​​​‌ is based on an​ offline-online decomposition. The offline​‌ stage is time-consuming, but​​ it is only executed​​​‌ once, whereas the online​ stage employs coarser grids​‌ and thus, is significantly​​ less expensive than a​​​‌ fine HF evaluation. On​ the direct method, we​‌ prove on a classical​​ model problem, the heat​​​‌ equation, that HF evaluations​ of sensitivities reach an​‌ optimal convergence rate in​​ $L^{\infty }(\mathrm{0‌},T;{\mathrm{H}}_0^1\left(\mathrm{\Omega ‌}\right))$, and​​ then establish that these​​​‌ rates are recovered by​ the NIRB two-grid approximation.​‌ These results are supported​​ by numerical simulations. We​​​‌ then propose a new​ procedure that further reduces​‌ the computational costs of​​ the online step while​​​‌ only computing a coarse​ solution of the state​‌ equations. On the adjoint​​ state method, we propose​​​‌ a new algorithm that​ reduces both the state​‌ and adjoint solutions. All​​ numerical results are run​​​‌ with the model problem​ as well as a​‌ more complex problem, namely​​ the Brusselator system

6.6.1 Reversed one-shot inversion​‌ methods

E. Abida, M.​​ Bonazzoli, H. Haddar

We​​​‌ are interested in the​ so-called one-shot methods for​‌ the solution of inverse​​ problems via gradient-based optimization​​​‌ algorithms. The idea of​ the one-shot approach is​‌ to couple the iterations​​ on the state, on​​​‌ the adjoint state and​ on the parameter variable.​‌ In particular, the iterations​​ on the state and​​​‌ adjoint state are incomplete,​ that is, stopped before​‌ achieving convergence for the​​ associated forward and adjoint​​​‌ problems. Hence, an inexact​ gradient is used to​‌ update the parameter variable.​​ Nevertheless, the convergence of​​​‌ the coupled iterations can​ still be achieved. We​‌ have recently performed a​​ numerical investigation for a​​​‌ variant where the one-shot​ iteration order is reversed​‌ so that an actual​​ descent direction is used​​​‌ at each iteration. We​ have analyzed this reversed​‌ one-shot method with one​​ inner iteration in the​​​‌ scalar case.

6.6.2 Imaging​ dam-rock interfaces in gravity​‌ dams

L. Audibert, M.​​ Bonazzoli, M. A. Boukraa,​​​‌ H. Haddar, D. Vautrin​

We are interested in​‌ imaging the interface between​​ the concrete structure of​​​‌ a hydroelectric gravity dam​ and the underlying rock,​‌ using Full Waveform Inversion.​​ Indeed, it appears that​​​‌ the roughness of the​ dam-rock interface has an​‌ effect on the sliding​​ stability of gravity dams.​​ We minimize a regularized​​​‌ misfit cost functional by‌ computing its shape derivative‌​‌ and iteratively updating the​​ interface shape by the​​​‌ gradient descent method. Numerical‌ results using realistic noisy‌​‌ synthetic data demonstrate the​​ method ability to accurately​​​‌ reconstruct the dam-rock interface‌ with a limited number‌​‌ of measurements and in​​ the presence of noise.​​​‌ Moreover, the algorithm appears‌ to be robust with‌​‌ respect to the heterogeneities​​ in the concrete that​​​‌ are typically expected in‌ the dam. An article‌​‌ is under preparation.

6.6.3​​ Silent sources on a​​​‌ surface for the Helmholtz‌ equation and decomposition of‌​‌ $L^2$ vector fields​​

L. Bratchart, H. Haddar,​​​‌ C.V. Guillén

We study‌ an inverse source problem‌​‌ with right hand side​​ in divergence form for​​​‌ the Helmholtz equation, whose‌ underlying model can be‌​‌ related to weak scattering​​ from thin interfaces. This​​​‌ inverse problem is not‌ uniquely solvable, as the‌​‌ forward operator has infinite-dimensional​​ kernel. We present a​​​‌ decomposition of (not necessarily‌ tangent) vector fields of‌​‌ $L^2$-class on​​ a closed Lipschitz surface​​​‌ in $R^3$,‌ which allows one to‌​‌ discuss an ansatz for​​ the solution and constraints​​​‌ that restore uniqueness. This‌ work can be seen‌​‌ as a generalization of​​ results in the literature​​​‌ dealing with the Laplace‌ equation, but in the‌​‌ Helmholtz case new ties​​ arise between the observations​​​‌ from each side of‌ the surface. Our proof‌​‌ is based on properties​​ of the Calderón projector​​​‌ on the boundary of‌ Lipschitz domains, that we‌​‌ establish in a ${\mathrm{H}}^{-1}\times {\mathrm{L‌}}^2$ setting.

8.1.1 Associate Teams in​​​‌ the framework of an‌ Inria International Lab or‌​‌ in the framework of​​ an Inria International Program​​​‌

8.2.1 Visits​ of international scientists

8.2.2​​ Visits to international teams​​​‌

Action exploratoire OptiGPR3D

Participants:​​ Lorenzo Audibert, Marcella​​​‌ Bonazzoli, Houssem Haddar​, Frédéric Taillade.​‌

• Title:
  Action exploratoire OptiGPR3D​​ (Optimal direct and​​​‌ inverse modeling for 3D​ GPR imaging in complex​‌ environments)
• Partner Institution(s):​​
  IDEFIX (Inria, EDF, ENSTA​​​‌ Paris), POEMS (CNRS, Inria,​ ENSTA Paris)
• Duration:
  Start:​‌ 05/2022, 4 years
• Coordinators:​​
  Marcella Bonazzoli (IDEFIX, Inria),​​​‌ Pierre Marchand (POEMS, Inria)​
• Administrator:
  Inria

"Biomedical Engineering​‌ Seed Grant Program" funded​​ by the Fondation Bettencourt​​​‌ Schueller

Participants: J.-R. Li​, A. McSweeney-Davis,​‌ S. Sedlar.

• Title:​​
  Investigation of potential biomarkers​​​‌ to detect chronic inflammation​ in Multiple Sclerosis through​‌ diffusion MRI
• Partner Institution(s):​​
  IDEFIX (Inria, EDF, ENSTA​​​‌ Paris), CHU de Rennes,​ Univ Rennes
• Duration:
  09/2023​‌ - 12/2025
• Coordinators:
  J.-R.​​ Li (IDEFIX, Inria), Anne​​​‌ Kerbrat (CHU de Rennes)​
• Administrator:
  Inria

9.1.1 Scientific events: organisation​​​‌

9.1.2 Scientific events: selection​​​‌

9.1.3​‌ Journal

9.1.4​​​‌ Invited talks

• M. Bonazzoli,‌ SIMAI 2025, biennial congress‌​‌ of the Italian Society​​ of Applied and Industrial​​​‌ Mathematics, Trieste, Italy, Sep.‌ 2025.
• M. Bonazzoli, DD29,‌​‌ International Conference on Domain​​ Decomposition Methods, Milan, Italy,​​​‌ Jun. 2025.
• M. Bonazzoli,‌ Fluid Mechanics and Waves‌​‌ seminar at the New​​ Jersey Institute of Technology,​​​‌ United States (online), Nov.‌ 2025.
• M. Bonazzoli, Seminar‌​‌ in Numerical Analysis at​​ University of Basel, Switzerland,​​​‌ Oct. 2025.
• M. Bonazzoli,‌ Seminar of Applied Mathematics‌​‌ at Università di Pavia,​​ Italy, Sep. 2025.
• M.​​​‌ Bonazzoli, Seminar at MOX‌ Laboratory, Politecnico di Milano,‌​‌ Italy, Sep. 2025.
• M.​​ Bonazzoli, Seminar of the​​​‌ Laboratoire de Mathématiques Appliquées‌ de Compiègne, France, Mar.‌​‌ 2025.
• L. Chesnel, conference​​ "Wave propagation in guiding​​​‌ structures", CIRM, Marseille, Oct.‌ 2025.
• L. Chesnel gave‌​‌ a course untitled "A​​ few techniques to achieve​​​‌ invisibility in waveguides", Summer‌ school EUR MINT 2025‌​‌ - Control, Inverse Problems​​ and Spectral Theory, Toulouse,​​​‌ Jun. 2025. 5.5h. Corresponding‌ lecture notes 19.‌​‌
• Z. Moitier, Seminar LAREMA​​ at Angers, May. 2025.​​​‌
• Z. Moitier, Seminar IDEFIX‌ at Palaiseau, April 2025.‌​‌
• Z. Moitier, Seminar MAC​​ at Toulouse, Feb. 2025.​​​‌
• H. Montanelli, Inverse Problems:‌ from Foundations to Applications,‌​‌ Marseille, September 2025.
• H.​​ Montanelli, Journée EDP &​​​‌ Analyse Numérique, Inria, ENSTA‌ and École Polytechnique, Juin‌​‌ 2025.
• H. Haddar, Conférence​​ WICOM, Paris, June 2025.​​​‌
• H. Haddar, Journées Onera‌ pour le CND en‌​‌ aéronautique, Chatillon, June 2025.​​

9.1.5 Research administration

• M.​​​‌ Bonazzoli is the International‌ partnerships Scientific Correspondent for‌​‌ Inria Saclay.
• M. Bonazzoli​​ took part in Mar.​​​‌ 2025 to the prize‌ committee for SMAI-GAMNI PhD‌​‌ Award 2025.
• M.​​ Bonazzoli took part in​​​‌ Jul. 2025 to the‌ prize committee for Prix‌​‌ Junior Maryam Mirzakhani awarded​​ by Fondation Mathématique Jacques-Hadamard​​​‌ (FMJH) to young female‌ students for a mathematics‌​‌ project.
• M. Bonazzoli took​​ part in Jun. 2025​​​‌ to the committee for‌ FMJH Care incoming mobility‌​‌ scholarships offered by FMJH​​ to enable excellent foreign​​​‌ students with limited resources‌ to join its Bachelor's‌​‌ or Master's programs in​​ mathematics.
• M. Bonazzoli is​​​‌ a volunteer member of‌ Opération Postes (newsletter and‌​‌ website, which gathers detailed​​ information about the French​​​‌ competitive selections for permanent‌ positions in Mathematics and‌​‌ Informatics, supported by the​​ French academic societies SMAI,​​​‌ SAGIP, SFdS, SIF, and‌ SMF).

9.2.1 Teaching

• Bachelor: L.‌ Chesnel, Numerical Methods for‌​‌ ODEs, 3rd year of​​ the Bachelor of Ecole​​​‌ Polytechnique, 20 TD hours.‌
• Master: L. Chesnel, Analyse‌​‌ variationnelle des équations aux​​ dérivées partielles, 2nd year​​​‌ of Ecole Polytechnique, 40‌ TD hours.
• Master: L.‌​‌ Chesnel, Modal - Modélisation​​ mathématique par la démarche​​​‌ expérimentale, 2nd year of‌ Ecole Polytechnique, creation and‌​‌ supervision of two projects​​ for six students.
• Master:​​​‌ L. Chesnel, cosupervision of‌ a psc project of‌​‌ four students, 2nd year​​ of Ecole Polytechnique, 2h​​​‌ meetings every 3 weeks.‌
• Bachelor: M. Bonazzoli, Fonctions‌​‌ de variable complexe, 1st​​ year of Engineer School,​​​‌ ENSTA, 12 TD hours.‌
• Master: M. Bonazzoli, Calcul‌​‌ scientifique parallèle, 3rd year​​​‌ of Engineer School and​ 2nd year of Master,​‌ ENSTA, 7 equivalent TD​​ hours.
• Lorenzo Audibert
  • Bachelor:​​​‌ Introduction to the discretization​ of partial differential equation​‌ with finite differences, for​​ students in the first​​​‌ year of ENSTA curriculum.​ 2022-2024.
  • Bachelor: Optimization, for​‌ students in the first​​ year of ENSTA curriculum.​​​‌ 2023-.
  • Bachelor: Dynamical Systems,​ for students in the​‌ first year of ENSTA​​ curriculum. 2025-.
• Zoïs Moitier​​​‌
  • Bachelor: Fonctions d'une variable​ complexe, ENSTA 1A,​‌ 15h (TD).
  • Bachelor: Introduction​​ aux probabilités, ENSTA​​​‌ 1A, 15h (TD).
  • Master:​ Eléments finis, ENSTA​‌ 2A, 15h (TD/TP).
  • Master:​​ Analyse fonctionnelle, ENSTA​​​‌ 2A, 15h (TD).
  • Tutoring​ ENSTA student, 21h eq.​‌ TD.
• Hadrien Montanelli
  • APM​​ 43035 EP — Optimization​​​‌ & Control (TA), 20h,​ École Polytechnique.
  • APM 52009​‌ EP — Machine Learning​​ for Scientific Computing &​​​‌ Numerical Analysis (Lecturer), 18h,​ École Polytechnique.
  • APM 41012​‌ EP — Introduction to​​ Numerical Analysis (TA), 20h,​​​‌ École Polytechnique 20.​
• Houssem Haddar
  • Bachelor: Elementary​‌ tools of analysis for​​ partial differential equations, for​​​‌ students in the first​ year of Ensta curriculum.​‌ 28 equivalent TD hours.​​
  • Bachelor: Optimization quadratique. Lecture​​​‌ course (for the entire​ cohort and tutori- als​‌ for first-year students in​​ the ENSTA curriculum. 24​​​‌ equivalent TD hours.

9.2.2​ Supervision

• Master internship: E.​‌ Abida, Analysis of a​​ new variant of the​​​‌ one-shot methods for inverse​ problems, (Apr–Sep. 2025), M.​‌ Bonazzoli and H. Haddar.​​
• Master internship: T. Creuset,​​​‌ Perfect transmission in periodic​ waveguides with localized defects,​‌ (Apr–Sep. 2025), L. Chesnel​​ and Z. Moitier.
• PhD​​​‌ in progress: A. Boisneault,​ Numerical methods and high​‌ performance simulation for 3D​​ imaging in complex media,​​​‌ (2023-), M. Bonazzoli (with​ X. Claeys, ENSTA, and​‌ P. Marchand, Inria).
• PhD​​ in progress: C. Hivart,​​​‌ Sampling Methods for concrete​ like material, (2024-), L.​‌ Audibert and H. Haddar​​
• PhD in progress: A.​​​‌ McSweeney-Davis, Modelling of wave​ propagation in heterogeneous moving​‌ fluid, (2024-), L. Audibert​​ and H. Haddar
• PhD​​​‌ in progress: M. Chavanne,​ Spectral Signature for Maxwell​‌ equations, (2024-), L. Audibert​​ and H. Haddar
• PhD​​​‌ in progress: A. Boisneault,​ Numerical methods and high​‌ performance simulation for 3D​​ imaging in complex media,​​​‌ (2023-), M. Bonazzoli (with​ X. Claeys, ENSTA, and​‌ P. Marchand, Inria).
• PhD​​ defended (17/12/2025): A. Parigaux,​​​‌ Construction of transparent conditions​ for electromagnetic waveguides, analysis​‌ and applications, L. Chesnel​​ (with A.-S. Bonnet-BenDhia and​​​‌ S. Fliss, Poems).
• PhD​ defended (10/10/2025): M. Mathevet,​‌ Imagerie par courant de​​ Foucault des fissures et​​​‌ dépôts dans les GV​ par méthodes inverses, analysis​‌ and applications, L. Audibert​​ and H. Haddar.
• Postdoc:​​​‌ A. Rappaport, Domain decomposition​ methods for electromagnetic waves​‌ in anisotropic complex media,​​ (2025-), M. Bonazzoli (with​​​‌ P. Ciarlet, ENSTA, and​ A. Modave, CNRS).
• Postdoc:​‌ M. Zaccaron, Invisibility in​​ electromagnetic waveguides, (01/09/2025-), L.​​​‌ Chesnel.
• PhD in progress:​ V. Chenu, SiML applied​‌ to linear sampling methods​​ (2024-). H. Motanelli and​​​‌ H. Haddar.
• PhD in​ progress: E. Jung, Curved​‌ boundary elements for elasticity​​ scattering problems (2025-). H.​​​‌ Motanelli and H. Haddar.​
• PhD in progress: C.​‌ Regaig, Kohn-Vogelius approach for​​ non symmetric inverse problems​​ (2024-). S. Chaabane and​​​‌ H. Haddar.

9.2.3 Juries‌

• M. Bonazzoli took part‌​‌ in Apr.–May 2025 in​​ the recruitment committee (​​​‌comité de sélection)‌ for the 2025 recruitment‌​‌ campaign of an Associate​​ professor (Maître de conférences)​​​‌ at Université de Lorraine.‌
• M. Bonazzoli took part‌​‌ in the PhD thesis​​ defense committee of Charlotte​​​‌ Milano (University of Reims‌ Champagne-Ardenne).

9.2.4 Participation in‌​‌ Live events

• M. Bonazzoli​​ participated to speed-meetings with​​​‌ female high school students‌ (Rendez-vous des Jeunes Mathématiciennes‌​‌ et Informaticiennes at Inria​​ Saclay, Oct. 2025), to​​​‌ answer their questions about‌ the studies and career‌​‌ as a mathematician.
• L.​​ Chesnel was volunteer at​​​‌ Inria stand at Fête‌ de la Science (Institut‌​‌ Polytechnique de Paris), Oct.​​ 2025.

International journals

• 2 article‌L.Lorenzo Audibert,‌​‌ H.Houssem Haddar and​​ F.Fabien Pourre.​​​‌ Averaged Steklov Eigenvalues, Inside‌ Outside Duality and Application‌​‌ to Inverse Scattering.​​SIAM Journal on Applied​​​‌ Mathematics2025. In‌ press. HALback to‌​‌ text
• 3 articleA.-S.​​Anne-Sophie Bonnet-Ben Dhia,​​​‌ L.Lucas Chesnel and‌ M.Mahran Rihani.‌​‌ Maxwell's equations with hypersingularities​​ at a negative index​​​‌ material conical tip.‌Pure and Applied Analysis‌​‌712025,​​ 127–169HAL
• 4 article​​​‌L.Lucas Chesnel,‌ H.Houssem Haddar,‌​‌ H.Hongjie Li and​​ J.Jingni Xiao.​​​‌ Examples of non-scattering inhomogeneities‌.Inverse Problems and‌​‌ Imaging 195October​​ 2025HALback to​​​‌ text
• 5 articleL.‌Lucas Chesnel and S.‌​‌ A.Sergei A Nazarov​​. On the breathing​​​‌ of spectral bands in‌ periodic quantum waveguides with‌​‌ inflating resonators.ESAIM:​​ Mathematical Modelling and Numerical​​​‌ Analysis5942025‌HALback to text‌​‌
• 6 articleE.Elise​​ Grosjean and B.Bernd​​​‌ Simeon. The non-intrusive‌ reduced basis two-grid method‌​‌ applied to sensitivity analysis​​.ESAIM: Mathematical Modelling​​​‌ and Numerical Analysis59‌1January 2025,‌​‌ 101-135HALDOI
• 7​​ articleH.Houssem Haddar​​​‌ and N.Nouha Jenhani‌. Analysis of the‌​‌ interior transmission problem in​​ an unbounded locally perturbed​​​‌ periodic strip.Inverse‌ Problems and Imaging 20‌​‌2025, 305-329In​​ press. HALDOIback​​​‌ to text
• 8 article‌A.Alex Mcsweeney-Davis,‌​‌ C.Chengran Fang,​​ E.Emmanuel Caruyer,​​​‌ A.Anne Kerbrat and‌ J.-R.Jing-Rebecca Li.‌​‌ Alpha Mesh Swc: automatic​​ and robust surface mesh​​​‌ generation from the skeleton‌ description of brain cells‌​‌.Briefings in Bioinformatics​​263January 2025​​​‌HALDOI

International peer-reviewed‌ conferences

• 9 inproceedingsA.-S.‌​‌Anne-Sophie Bonnet-Ben Dhia,​​ L.Lucas Chesnel,​​​‌ S.Sonia Fliss and‌ A.Aurélien Parigaux.‌​‌ Mathematical and numerical analysis​​ of the modes of​​​‌ a heterogeneous electromagnetic waveguide.‌.WAVES 2025 -‌​‌ Conference on Mathematics of​​ Wave PhenomenaKarlsruhe, Germany​​​‌February 2025HALback‌ to text

Conferences without‌​‌ proceedings

• 10 inproceedingsM.​​​‌Mohamed Belmokhtar, N.​Nabil Maifia, G.​‌Géraldine Villain, D.​​Denis Vautrin and A.​​​‌Alexis Cothenet. Approaches​ and limitations of Non-Destructive​‌ Testing for evaluating bituminous​​ concrete using wave propagation:​​​‌ A review from the​ laboratory test to in​‌ situ case study.​​International Symposium on Nondestructive​​​‌ Testing in Civil Engineering​ (NDT-CE 2025)3010​‌IZMIR, TurkeyOctober 2025​​HALDOI
• 11 inproceedings​​​‌N.Nabil Maifia,​ M.Mohamed Belmokhtar,​‌ G.Géraldine Villain,​​ D.Denis Vautrin,​​​‌ F.Frédéric Taillade and​ A.Alexis Cothenet.​‌ Non-Destructive Ultrasonic Evaluation of​​ Asphalt Concrete Waterproofing in​​​‌ Hydraulic Structures: Experimental and​ Numerical Study.International​‌ Symposium on Nondestructive Testing​​ in Civil Engineering (NDT-CE​​​‌ 2025)3010IZMIR,​ TurkeyOctober 2025HAL​‌DOI

Reports & preprints​​

• 12 miscA.Antonin​​​‌ Boisneault, M.Marcella​ Bonazzoli, X.Xavier​‌ Claeys and P.Pierre​​ Marchand. Spurious resonances​​​‌ for substructured FEM-BEM coupling​.November 2025HAL​‌back to text
• 13​​ miscM.Marcella Bonazzoli​​​‌, G.Gabriele Ciaramella​ and I.Ilario Mazzieri​‌. On the unmapped​​ tent pitching for the​​​‌ heterogeneous wave equation.​December 2025HALback​‌ to text
• 14 misc​​A.-S.Anne-Sophie Bonnet-Ben Dhia​​​‌, L.Lucas Chesnel​ and S.Sonia Fliss​‌. Trapped modes in​​ electromagnetic waveguides.December​​​‌ 2025HALback to​ text
• 15 miscD.-Q.​‌Duc-Quang Bui, B.​​Bérangère Delourme, L.​​​‌Laurence Halpern and F.​Felix Kwok. Optimized​‌ Schwarz Methods in Time​​ for Discrete Transport Control​​​‌.June 2025HAL​
• 16 miscL.Lucas​‌ Chesnel and S. A.​​Sergei A. Nazarov.​​​‌ Eigenvalue falls in thin​ broken quantum strips.​‌August 2025HALback​​ to text
• 17 misc​​​‌L.Luiz Faria,​ P.Pierre Marchand and​‌ H.Hadrien Montanelli.​​ Convergence rates of curved​​​‌ boundary element methods for​ the 3D Laplace and​‌ Helmholtz equations.July​​ 2025HALback to​​​‌ text
• 18 miscH.​Hadrien Montanelli, R.​‌ M.Richard Mikael Slevinsky​​ and Q.Qiang Du​​​‌. Nonlocal vector calculus​ on the sphere.​‌2025HALDOIback​​ to text

Educational activities​​​‌

• 19 unpublishedL.Lucas​ Chesnel. A few​‌ techniques to achieve invisibility​​ in waveguides.June​​​‌ 2025, DoctoralFrance​HALback to text​‌
• 20 unpublishedH.Hadrien​​ Montanelli. Machine Learning​​​‌ for Scientific Computing and​ Numerical Analysis.January​‌ 2025, MasterFrance​​HALback to text​​​‌