3.3.1 Optimization, variational calculus and numerical schemes

We are interested in non-convex optimization problems, especially those raised by variational calculus. While the convergence of numerical schemes is well established for convex problems, this is not always the case for non-convex functionals. Our aim is to continue the work already carried out in the biconvex framework 7, and extend it to primal-dual algorithms. We especially want to address energy minimization problems where the energy is convex with respect to each variable, but non-convex with respect to the pair of variables.

Another research topic is to investigate new neural architectures adapted to non-Euclidean data, and also to plug variational methods into deep learning approaches to regularize the results. The obtained theoretical results will be applied to image colorization, with the idea to reduce artefacts caused both by a lack of regularization and by the non-Euclidean structure of color information as perceived by the human visual system.

3.3.2 Machine learning for physical problems

We aim at continuing our efforts towards supervised and unsupervised learning for estimation problems. Concerning supervised learning, we intend to investigate further the opportunities offered by neural network estimation of displacement and strain fields in experimental mechanics that we have recently introduced with colleagues in mechanics and signal processing 1. Besides, we also aim at developing unsupervised learning in problems where a quantity has to be estimated over a spatio-temporal domain, which is a recent trend in several application domains. Neural networks are indeed universal approximators whose derivative can be exactly computed with the backpropagation algorithm, which is supposed to make them robust to acquisition noise.

6.1.1 DeepEllPose

• Name:
  Deep Ellipses Pose
• Keywords:
  Pose estimation, Visual localization, Ellipses, Neural networks
• Functional Description:
  DeepEllPose contains the training and inference code of the object detection and ellipse prediction networks (PyTorch). This code corresponds to an extended implementation of the article: 3D-Aware Ellipse Prediction for Object-Based Camera Pose Estimation 13. The 7-Scenes dataset is used as example, but the provided tools make it easily applicable to other datasets. The library also contains the code for camera pose estimation from 3 pairs ellipse-ellipsoid, as well as tools to easily manipulate and visualize such objects.
• URL:
  https://­gitlab.­inria.­fr/­tangram/­3d-aware-ellipses-for-visual-localization
• Contact:
  Matthieu Zins

6.1.2 OA-SLAM

• Name:
  Object -aided SLAM
• Keywords:
  Localization, 3D reconstruction, Object detection
• Scientific Description:
  Details on the method can be found in the paper published in ISMAR 2022 15.
• Functional Description:
  OA-SLAM uses objects as landmarks to improve the relocalization capabilities of SLAM systems. OA-SLAM builds on the point-based ORB-SLAM2. It allows online reconstruction of 3D objects modeled as ellipsoids from their detections in 2D images. OA-SLAM dramatically improves the relocalization capabilities of SLAM.
• URL:
  https://­gitlab.­inria.­fr/­tangram/­oa-slam
• Contact:
  Matthieu Zins

7.3.1 Individual mitral valve modeling

We previously worked on the segmentation of the valve anatomy and started last year a work on modeling mitral valve closure using fluid-structure interaction (FSI). This year, we focused first on a FSI model with a generic valve that improves the detection of blood leakage by building a map of contact 10. Our model is based on the immersed boundary method that captures a map of contact and perfect closure of the mitral valve, without the presence of orifice holes, which often appear with existing methods. We also identified important factors influencing convergence issues. Our method was demonstrated in three typical clinical situations: mitral valve with leakage, bulging, and healthy. In addition to the classical ways of evaluating mitral valve closure, such as stress distribution and flow rate, the contact map provides easy detection of leakage with identification of the sources of leakage and a quality assessment of the closure.

We then started to work on incorporating anisotropy in our model to get closer to the real valve behavior. Results on our generic model show that anisotropy leads to less bulging than using an isotropic constitutive law, which is consistent with clinician observations. We are currently investigating valve mitral closure simulation from real valve automatically segmented from porcine data.

7.3.2 Image-based biomechanical simulation of the diaphragm during mechanical ventilation

Following our previous research on modeling the diaphragm with a Radial Basis Function (RBF) formulation within the INVIVE project, we focused this year on 2D simulations 11. We used a system of partial differential equations that model linear elasticity. We computed displacements and stresses in a 2D cross section of the diaphragm in its contracted state. The boundary conditions consist of a mix of displacement and traction conditions. If these are imposed as they are, and the conditions are not compatible, this leads to reduced smoothness of the solution. Therefore, the boundary data was first smoothed using the least-squares RBF generated finite difference framework. Then the boundary conditions were reformulated as a Robin boundary condition with smooth coefficients. The same framework was also used to approximate the boundary curve of the diaphragm cross section based on data obtained from a slice of a CT scan. To solve the PDE we employed the unfitted least-squares RBF method. This made it easier to handle the geometry of the diaphragm, which is thin and non-convex. We showed numerically that our solution converges with high-order towards a finite element solution evaluated on a fine grid. Through this simplified numerical model, we also gained an insight into the challenges associated with the diaphragm geometry and the boundary conditions before approaching a more complex three-dimensional model.

7.4.1 Detection of brain aneurysms using deep learning

Youssef Assis's PhD thesis aims at the detection of brain aneurysms from 3D Time-of-Flight (TOF) MRI images with a deep learning approach. A preliminary clinical evaluation of last year's method 16 led us to revisit the methodology used by the ADAM challenge and most publications about the detection of brain aneurysms with deep learning techniques. In their vast majority, such methods rely on a U-net architecture, which was designed for segmentation problems. The usual criteria used to evaluate their performance (e.g. based on connected component extraction) are thereafter not suited to a detection problem. We reassessed our method against performance measures used in computer vision for detection problems (e.g. Average Precision (AP)). We also implemented an anchor-free version of YOLOv3 that processes 3D patches as input and outputs a bounding sphere associated with a level of confidence on the detection within the patch. We compared this new network against nnDetection1 on 3 databases: an in-house dataset, collected in Nancy University Hospital with our medical partners (132 patients), ADAM training database (93 subjects) and CHUV Lausanne public database. Our results demonstrate an improved performance slightly better sensitivity, fewer False Positives/case) with a much reduced training time. These results are currently being exhaustively reviewed by medical experts for consolidation with regard to the many annotations errors in the databases.

7.4.2 Clinical evaluation of registration and segmentation software

Our work in collaboration with Nancy University Hospital and GE Healthcare company was presented at ABC-Win seminar 17. It addressed the clinical evaluation of a blood vessel segmentation and brain image registration software to help planning and performing the endovascular treatment of brain arteriovenous malformations.

7.4.3 Predictive simulation of catheter navigation

Off-the-shelf catheter simulation algorithms made available by the Sofa framework were investigated through a comparison with ground-truth catheter shapes reconstructed with our experimental validation bench (real catheters reconstructed by stereovision while deployed in a vascular phantom in silicon). Despite their capacity to perform interactively, these algorithms demonstrated a low accuracy, that cannot meet the requirements for planning interventional neuroradiology procedures. Radhouane Jilani's PhD thesis aims to achieve collision with implicit, continuous, blood vessel surfaces 4. Therefore, we investigated Cosserat rod models designed for continuous robots. Such methods consider the rod a parametric function instead of a sequence of discrete elements. The derived Boundary Value Problem (BVP) can be solved using the shooting method or a collocation method. We adapted the collocation method to be used with an implicit dynamics framework and proved its superior stability over a wider range of deformations.

7.5.1 Computational photomechanics

The work of this year concerns deep learning networks able to estimate the displacement and strain fields over a material submitted to a mechanical load. Displacement field estimation is related to optical flow estimation in computer vision 19. In order to process the surface of the material, a contrasted marking is projected on it, giving a speckle pattern. The first goal was to customize a state-of-the-art convolutional neural network dedicated to optical flow estimation (processing natural images) to reach better performance when processing speckle images. The second goal was to simplify the CNN by reducing as much as possible the number of filters while keeping equivalent metrological performance to the original version (and almost equivalent to state-of-the-art digital image correlation estimation), in order to accelerate image processing on a power-efficient compact Graphics Processing Unit (GPU). The ultimate goal is to develop smart-cameras dedicated to displacement and strain measurement. A paper journal has been accepted at the end of year 2022 9.

7.5.2 Variational methods for image processing

During the internship of Gaetano Agazzotti, the combination of deep image priors and variational method has been explored for single image colorization. The deep image prior model is able to produce realistic image while suffering of overfitting of the data that produces noisy images and blurring of the colorization results. With a regularization of the result with total variation, these effects can be avoided and controlled.

The colorization of videos is mostly based on color transfer between frames. The state-of-the-art methods suffer from occlusions and dis-occlusions during the matching phase. Since such problems are generally solved through 3D knowledge on the scene, the PhD thesis of Nicolas Maignan is aiming at understanding the 3D scene from a monocular video sequence.

7.6.1 Extensive searches for complex intermetallic catalysts

Materials science is at the heart of many technological revolutions. The search for new materials is crucial to meet the challenges posed by climate change, or the growing global demand for energy and consumer goods. In this context, the discovery of new catalytic materials is a major challenge to improve the performance of industrial processes, for example in the context of the hydrogen economy, in order to provide energy sources with limited environmental impact. Although some theoretical models exist, catalyst research is still largely empirical and based on a trial-and-error approach. This is probably because the application of theoretical models requires particularly expensive calculations based on density functional theory (DFT). Recently, the materials community has been seizing on statistical learning tools to limit the cost of calculations and to accelerate the discovery of new catalysts. Together with Emilie Gaudry at Institut Jean-Lamour (IJL) at Nancy, we have developed a collaboration on this subject since September 2021 through Nathan Boulangeot's PhD thesis. The work of this year concerns developping models for infering the energy of the system and the forces applied to the atoms in the context of predicting the adsorption properties of ${Al}_{13}{Co}_4$, based on Gaussian process regression.

7.6.2 Multivariate analysis of geochemical, physical and mineralogical signatures of uranium deposits in the Athabasca Basin (Saskatchewan, Canada)

We are engaged in the co-supervision (together with Julien Mercadier, GéoRessources) of the PhD thesis of Mehdi Serdoun, which is part of the GeoMin3D project funded by ANR and Orano Mining. The goal is to develop statistical learning models to analyze the large amount of data of diverse nature provided during the exploratory drillings in Athabasca basin, the largest known source of uranium. The ultimate goal is to develop new analysis tools to accelerate exploration and reduce its cost, in cooperation with the industrial actors.

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

8.3.1 Other european programs/initiatives

ANR Arcé

• Title:
• Partner Institution(s): Université de Lorraine
• Participants:
  F. Pierre, N. Maignan, F. Sur
• Date/Duration:
  2019-2022
• Additionnal info/keywords:
  The Arcé project aims at proposing new methods for automatic, fast and perceptually satisfying video colorization. Image colorization methods based on deep learning based have encountered a great success in recent years. These techniques are fully automatic and very fast, but they have not been adopted by colorization industry. The reason is that they do not ensure the temporal coherence of the colorization, which is particularly disturbing for the viewer. The ultimate goal is the use of our work in audiovisual production studios.

ANR JCJC ICaRes

• Title:
  Image correlation for the accurate measurement of residual stress
• Partner Institution(s):
  Université Clermont-Auvergne
• Participants:
  F. Sur
• Date/Duration:
  2019-2022
• Additionnal info/keywords:
  This 3-year project (2019-2022) headed by B. Blaysat (Université Clermont-Auvergne), is supported by the Agence Nationale de la Recherche. It addresses residual stresses, which are introduced in the bulk of materials during processing or manufacturing. Since unintended residual stresses often initiate early failure, it is of utmost importance to correctly measure them. The goal of the ICaRes project is to improve the performance of residual stress estimation through the so-called virtual digital image correlation (DIC) which will be developed. The basic idea of virtual DIC is to mark the specimen with virtual images coming from a controlled continuous image model, instead of the standard random pattern. Virtual DIC is expected to outperform standard DIC by, first, matching real images of the materials with the virtual images, then, to run DIC on the virtual images on which strain fields are estimated, giving ultimately residual stresses.

ANR PRC PreSPIN

• Title:
  Predictive Simulation for Planning Interventional Neuroradiology procedures
• Partner Institution(s):
  CReSTIC (Reims), Creatis (Lyon) and CIC-IT/CHRU Nancy
• Participants:
  R. Jilani, E. Kerrien, P.-F Villard.
• Date/Duration:
  2020-2024
• Additionnal info/keywords:
  This 4-year project is coordinated by E. Kerrien. It aims at improving the planning phase in the therapeutic management of cerebral ischemic strokes thanks to predictive simulation of both the therapeutic interventional gesture and post-interventional perfusion images. The consortium is set to address the challenges of geometrical and topological modeling of the full brain vasculature; physics-based simulation of interventional devices; simulation of MRI perfusion images; and clinical validation.

9.1.1 Scientific events: selection

9.1.2 Journal

9.1.3 Invited talks

• Pierre-Frédéric Villard did a presentation to the Harvard Biorobotics Lab within the CURATIVE collaboration. Title: "Mitral Valve Modeling: From Medical Image Analysis to Fluid Structure Interaction" on Nov 17th 2022.
• Nariman Khaledian did a presentation to the Harvard Biorobotics Lab within the CURATIVE collaboration. Title: "Capturing Contact in Mitral Valve Dynamic Closure with Fluid-Structure Interaction Simulation" on January 14th 2022.
• Pierre-Frédéric Villard gave a seminar at the department of information technology of Uppsala University. Title: "Simulation of Mitral Closing" on May 19th 2022.
• Romain Boisseau and Alain Pagani gave a presentation of the MOVEON project at the VIVATECH event. Title: "Towards Robust Spatial Scene Understanding in Dynamic environments Using Intermediate Representations", on June 17th 2022.
• Erwan Kerrien gave an invited lecture during the scientific days of FLI-RE3 in Strasbourg (French research network on interventional imaging, part of the France Life Imaging infrastructure). Title "Simulation for the planning of endovascular thrombectomy" on June 29th 2022.

9.1.4 Leadership within the scientific community

• Marie-Odile Berger is the president of the Association française pour la reconnaissance et l’interprétation des formes (AFRIF).

9.1.5 Scientific expertise

• Marie-Odile Berger was a member of the recruitment committee for a Professor position at INSA Rennes and at Université de Strasbourg

9.1.6 Research administration

• Marie-Odile Berger was the president of a jury for the recruitement of a research engineer specialized in computer graphics at INRIA Nancy Grand Est
• Gilles Simon is an elected member of the CNU (Conseil National des Universités).

9.2.1 Teaching

The assistant professors of the TANGRAM team actively teach at Université de Lorraine with an annual number of around 200 teaching hours in computer sciences, some of them being accomplished in the field of image processing. INRIA researchers have punctual teaching activities in computer vision and shape recognition mainly in the computer science Master of Nancy and in several Engineering Schools near Nancy (ENSMN Nancy, SUPELEC Metz, ENSG). Our goal is to attract Master students with good skills in applied mathematics towards the field of computer vision.

The list of courses given by staff members which are related to image processing and computer vision is detailed below:

• M.-O. Berger
  • Master : Shape recognition, 24 h, Université de Lorraine.
  • Master : Introduction to image processing, 12 h, ENSMN Nancy.
  • Master : Image processing for Geosciences, 12h, ENSG.
• E. Kerrien
  • Master : Introduction to image processing, 15 h, ENSMN Nancy.
  • Licence : Initiation au développement, 80h, IUT St Dié-des-Vosges.
• Fabien Pierre
  • Master: Introduction à l’apprentissage automatique, 14h, Mines Nancy.
  • Master: Vision artificielle et traitement des images, 12h, Polytech Nancy.
  • Licence: Introduction au traitement d’image, 30h, IUT Saint-Dié des Vosges.
  • Licence: Algorithmique et programmation, 87h, IUT Saint-Dié des Vosges
  • Licence: Culture scientifique et traitement de l’information, 69h, IUT Saint-Dié des Vosges
  • Licence: Programmation objet et évènementielle, 35h, IUT Saint-Dié des Vosges
  • Licence: Initiation à l’intelligence artificielle, 18h, IUT Saint-Dié des Vosges
• G. Simon
  • Master: Augmented reality, 9 h, Télécom-Nancy.
  • Master: Augmented reality, 24h, M2 Informatique FST
  • Master: Visual data modeling, 12h, M1 Informatique FST
  • Master: Computer Vision, 12h, M1 Informatique FST
  • Licence pro: 3D modeling and augmented reality, 50h FST - CESS d’Epinal
  • Licence: Programming methodology, L1 informatique, 48h FST
• F. Sur
  • Master: Introduction to machine learning, 40 h, Université de Lorraine (Mines Nancy).
  • Licence: Javascript programming, 100h, IUT Charlemagne
• P.-F Villard
  • Master : Augmented and Virtual Reality, 16h, M2 Cognitive Sciences and Applications, Institut des Sciences du Digital, Université de Lorraine
  • Licence: Computer Graphics with webGL, 30h, IUT Saint-Dié des Vosges.
  • Licence: Virtual and Augmented Reality in Industrial Maintenance, 2h, Faculty of Science and Technology, Université de Lorraine
  • Licence: Web programming, 20h, IUT Saint-Dié des Vosges.
  • Licence: Graphical user interface programming, 30h, IUT Saint-Dié des Vosges.
  • Licence: Security and life privacy with internet, 2h, IUT Saint-Dié des Vosges.
  • Licence: Parallel programming, 18h, IUT Saint-Dié des Vosges.
  • Licence: Initiation to machine learning, 24h, IUT Saint-Dié des Vosges.
  • Licence: Initiation to cryptography, 12h, IUT Saint-Dié des Vosges.
• B. Wrobel-Dautcourt
  • Master: modélisation objet et conception des systèmes d’information, 30h, Télécom
  • Master: projet de conception et développement java, 27h, Télécom 2A
  • Master: ingéniérie logicielle, 12h, FST
  • Licence: bases de la programmation objet, 44h, FST
  • Licence: interfaces graphiques,22h, FST
  • Licence: projet de synthèse (activité intégratrice), 30 h, FST
  • Licence: système, 24h, FST
  • Licence: compilation, 16h, FST

9.2.2 Supervision

• PhD defended: Matthieu Zins, Contribution à la précision et à la robustesse de la localization dans un monde d'objets, December 2022, Marie-Odile Berger, Gilles Simon.
• PhD in progress: Abdelkarim Elassam, Robust visual localization using high level features, October 2020, Marie-Odile Berger, Gilles Simon.
• PhD in progress: Nariman Khaledian, Toward a Functional Model of the Mitral Valve, October 2020, Marie-Odile Berger, Pierre-Frédéric Villard.
• PhD in progress: Youssef Assis, Deep learning for the automated detection of brain aneurysms, November 2020, Erwan Kerrien, René Anxionnat (CHRU Nancy).
• PhD in progress: Radhouane Jilani, Predictive simulation for interventional neuroradiology, October 2021, Erwan Kerrien, Pierre-Frédéric Villard.
• PhD in progress: Liang Liao, Detection of cerebral aneurysms from MRI images using deep learning: deep neural network creation and its clinical evaluation, November 2022, René Anxionnat (CHRU Nancy) and Erwan Kerrien.
• PhD in progress: Nathan Boulangeot, Extensive searches for complex intermetallic catalysts, October 2021, Émilie Gaudry (Institut Jean-Lamour), Frédéric Sur.
• PhD in progress: Mehdi Serdoun, Multivariate analysis of mineralogical, geochemical and physical signatures, January 2022, Julien Mercadier (GéoRessources), Frédéric Sur.
• PhD in progress: Nicolas Maignan, Image and video colorization, October 2022, Fabien Pierre, Frédéric Sur

9.2.3 Juries

• Marie-Odile Berger was president of the PhD committee of Pierre schegg (Inria Lille) and Semyon Efremov (Université de Lorraine) and of Romain Serizel's HDR committe ( Université de Loraine). She was external reviewer for the PhD thesis of Lulin Zhang (IGN), Matthieu Gonzalez (IRISA, Rennes) and Laurane Charrier (LISTIC, Annecy)
• Frédéric Sur was a member of the PhD committees of Mariane Prado Motta (LEM3 Saint-Dié-dès-Vosges) and Yiheng Shi (Université Clermont-Auvergne)
• Erwan Kerrien was an external reviewer for the PhD thesis of Guillaume Mestdagh (Université de Strasbourg) and was a member of the PhD committee of Rémi Decelle and Arturo Consoli (Université de Lorraine).

9.3.1 Internal or external Inria responsibilities

• Erwan Kerrien is Chargé de Mission for scientific mediation at Inria Nancy-Grand Est, and thereby is part of the Inria scientific mediation network. As such, he is a member of the steering committee of "la Maison pour la Science de Lorraine", and member of the IREM Lorraine (Institut de Recherche sur l’Enseignement des Mathématiques - Research Institute for Teaching Mathematics) steering council. He is also the local scientific referent for the "Chiche!" initiative.

9.3.2 Articles and contents

• A report on Gilles Simon's work 6 was broadcast on German television (D. Differdange, Versteckt: Informatiker aus Nancy entschlüsselt Van Eyck-Code, SR, Jan 2022).

9.3.3 Education

• Pierre-Frédéric Villard is the scientific godfather of the secondary school of Champigneulles (France) as a "Collège Pilote" of "La Main à la pâte" foundation. He gave a seminar on augmented and virtual realities to the pupils, he helped the teacher with preparing some activities with augmented and virtual reality technologies. Eventually, he is supervising master students to produce teaching applications with augmented reality technologies that will be used in secondary school classes.
• Pierre-Frédéric Villard presented a workshop on automatic character recognition using deep learning technique at the "Fête de la Science" in St-Dié-des-Vosges.
• Gilles Simon gave a talk at the Rosa Parks high school in Thionville on the theme "Geometry and happiness" as part of the "Regards de géomètres" event.
• Erwan Kerrien was an associate researcher to a MATh.en.JEANS workshop within Henri Loritz high school in Nancy. He presented the MATh.en.JEANS initiative during a DAAC workshop (Culture and Art Academic Direction). He also participates in the "Maths and games" group at IREM Lorraine.
• Erwan Kerrien animated a workshop about "Binary height charts" during the APMEP day (Maths teachers association in public education), and another one about "Images and statistics" during the NSI day (high school computer science teachers association).
• Pierre-Frédéric Villard and Erwan Kerrien did presentations to high school students in the context of the "Chiche!" initiative.

9.3.4 Interventions

• Gilles Simon participated in a conference-debate for the general public on the profession of researcher as part of the event "La Fabrique des chercheurs" at the university library of Vandœuvre-lès-Nancy.
• Erwan Kerrien and Gilles Simon proposed an animation at the "Nuit Européenne des chercheur.e.s" which took place in Nancy in October 2022.
• Erwan Kerrien gave a lecture about "Computer science: A science for every day life" in Strasbourg and again in Lycée Louis Vincent high school in Metz, both in connection with the Homo Numericus exposition designed by Inria Nancy Grand Est.

International journals

• 9 articleS.S. Boukhtache, K.K. Abdelouahab, A.A. Bahou, F.F. Berry, B.B. Blaysat, M.M. Grédiac and F.Frédéric Sur. A lightweight convolutional neural network as an alternative to DIC to measure in-plane displacement fields.Optics and Lasers in Engineering161February 2023, 107367
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• 10 articleN.Nariman Khaledian, P.-F.Pierre-Frédéric Villard and M.-O.Marie-Odile Berger. Capturing Contact in Mitral Valve Dynamic Closure with Fluid-Structure Interaction Simulation.International Journal of Computer Assisted Radiology and Surgery2022
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• 11 articleI.Igor Tominec, P.-F.Pierre-Frédéric Villard, E.Elisabeth Larsson, V.Víctor Bayona and N.Nicola Cacciani. An unfitted radial basis function generated finite difference method applied to thoracic diaphragm simulations.Journal of Computational PhysicsAugust 2022, 111496
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• 12 articleP.-F.Pierre-Frédéric Villard, M.Maureen Boudart, I.Ioana Ilea and F.Fabien Pierre. Anomaly Detection on Textured Images with Convolutional Neural Network for Quality Control of Micrometric Woven Meshes.Fluid Dynamic and Material Process1862022, 1639 - 1648
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• 13 articleM.Matthieu Zins, G.Gilles Simon and M.-O.Marie-Odile Berger. Object-Based Visual Camera Pose Estimation From Ellipsoidal Model and 3D-Aware Ellipse Prediction.International Journal of Computer Vision130March 2022, 1107–1126
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International peer-reviewed conferences

• 14 inproceedingsM.Matthieu Zins, G.Gilles Simon and M.-O.Marie-Odile Berger. Level Set-Based Camera Pose Estimation From Multiple 2D/3D Ellipse-Ellipsoid Correspondences.IROS 2022 - International Conference on Intelligent Robots and SystemsKyoto, JapanOctober 2022
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• 15 inproceedingsM.Matthieu Zins, G.Gilles Simon and M.-O.Marie-Odile Berger. OA-SLAM: Leveraging Objects for Camera Relocalization in Visual SLAM.ISMAR 2022 - 21st IEEE International Symposium on Mixed and Augmented RealitySingapour, SingaporeOctober 2022
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National peer-reviewed Conferences

• 16 inproceedingsL.Liang Liao, Y.Youssef Assis, F.Fabien Pierre, R.René Anxionnat and E.Erwan Kerrien. Une stratégie efficace de préparation des données pour la détection des anévrismes cérébraux en IRM 3D-TOF par deep learning.Journal of Neuroradiology49th Congress of the French Society of Neuroradiology4949th Congress of the French Society of Neuroradiology (Lyon, France)2Lyon, FranceMarch 2022, 118-119
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Conferences without proceedings

• 17 inproceedingsR.R Anxionnat, Y.Y Djebiret, E.Erwan Kerrien, M.-O.Marie-Odile Berger, I.I Cartier, S.S Amelot, Y.Y Trousset and S.S Bracard. EmboASSIST a new software to help endovascular treatment of brain AVMs.ABC-WIN SeminarVal d'Isère, FranceApril 2022
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• 18 inproceedingsA.A Elassam, G.G Simon and M.-O.M.-O Berger. Détection multiple de points de fuite horizontaux par deep learning.RFIAP 2022 - Reconnaissance des Formes, Image, Apprentissage et PerceptionVannes, FranceJuly 2022
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Scientific book chapters

• 19 inbookF.Frédéric Sur, B.Benoît Blaysat and M.Michel Grédiac. Which Pattern for a Low Pattern-Induced Bias?Thermomechanics & Infrared Imaging, Inverse Problem Methodologies, Mechanics of Additive & Advanced Manufactured Materials, and Advancements in Optical Methods & Digital Image Correlation, Volume 4Conference Proceedings of the Society for Experimental Mechanics SeriesSpringer International Publishing2022, 103-105
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Doctoral dissertations and habilitation theses

• 20 thesisM.Matthieu Zins. Contributions to the accuracy and robustness of visual localization in a world of objects.Université de lorraineDecember 2022
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