3.1 Discrete modeling of slender elastic structures

For the last 15 years, we have investigated new discrete models for solving the Kirchhoff dynamic equations for thin elastic rods  10, 12, 16. All our models share a curvature-based spatial discretization, allowing them to capture inextensibility of the rod intrinsically, without the need for adding any kinematic constraint. Moreover, elastic forces boil down to linear terms in the dynamic equations, making them well-suited for implicit integration. Interestingly, our discretization methodology can be interpreted from two different points-of-views. From the finite-elements point-of-view, our strain-based discrete schemes can be seen as discontinuous Galerkin methods of zero and first orders. From the multibody system dynamics point of view, our discrete models can be interpreted as deformable Lagrangian systems in finite dimension, for which a dedicated community has started to grow recently  37. We note that adopting the multibody system dynamics point of view helped us formulate a linear-time integration scheme  11, which had only be investigated in the case of multibody rigid bodies dynamics so far.

3.2 Discrete and continuous modeling of frictional contact

Most popular approaches in Computer Graphics and Mechanical Engineering consist in assuming that the objects in contact are locally compliant, allowing them to slightly penetrate each other. This is the principle of penalty-based methods (or molecular dynamics), which consists in adding mutual repulsive forces of the form $kf\left(\delta \right)$, where $\delta$ is the penetration depth detected at current time step  18, 34. Though simple to implement and computationally efficient, the penalty-based method often fails to prevent excessive penetration of the contacting objects, which may prove fatal in the case of thin objects as those may just end up traversing each other. One solution might be to set the stiffness factor $k$ to a large enough value, however this causes the introduction of parasitical high frequencies and calls for very small integration steps  9. Penalty-based approaches are thus generally not satisfying for ensuring robust contact handling.

In the same vein, the friction law between solid objects, or within a yield-stress fluid (used to model foam, sand, or cement, which, unlike water, cannot flow beyond a certain threshold), is commonly modeled using a regularized friction law (sometimes even with simple viscous forces), for the sake of simplicity and numerical tractability (see e.g., 36, 29). Such a model cannot capture the threshold effect that characterizes friction between contacting solids or within a yield-stress fluid. The nonsmooth transition between sticking and sliding is however responsible for significant visual features, such as the complex patterns resting on the outer surface of hair, the stable formation of sand piles, or typical stick-slip instabilities occurring during motion.

The search for a realistic, robust and stable frictional contact method encouraged us to depart from those, and instead to focus on rigid contact models coupled to the exact nonsmooth Coulomb law for friction (and respectively, to the exact nonsmooth Drucker-Prager law in the case of a fluid), which better integrate the effects of frictional contact at the macroscopic scale. This motivation was the sense of the hiring of F. Bertails-Descoubes in 2007 in the Inria/LJK Bipop team, specialized in nonsmooth mechanics and related convex optimization methods. In the line of F. Bertails-Descoubes's work performed in the Bipop team, the Elan team keeps on including some active research on the finding of robust frictional contact algorithms specialized for slender deformable structures.

3.3 Inverse design of slender elastic structures [ERC Gem ]

With the considerable advance of automatic image-based capture in Computer Vision and Computer Graphics these latest years, it becomes now affordable to acquire quickly and precisely the full 3D geometry of many mechanical objects featuring intricate shapes. Yet, while more and more geometrical data get collected and shared among the communities, there is currently very little study about how to infer the underlying mechanical properties of the captured objects merely from their geometrical configurations.

An important challenge consists in developing a non-invasive method for inferring the mechanical properties of complex objects from a minimal set of geometrical poses, in order to predict their dynamics. In contrast to classical inverse reconstruction methods, our claim is that 1/ the mere geometrical shape of physical objects reveals a lot about their underlying mechanical properties and 2/ this property can be fully leveraged for a wide range of objects featuring rich geometrical configurations, such as slender structures subject to contact and friction (e.g., folded cloth or twined filaments).

In addition to significant advances in fast image-based measurement of diverse mechanical materials stemming from physics, biology, or manufacturing, this research is expected in the long run to ease considerably the design of physically realistic virtual worlds, as well as to boost the creation of dynamic human doubles.

To achieve this goal, we shall develop an original inverse modeling strategy based upon the following research topics:

4.1 Mechanical Engineering

Many physicists and mathematicians have strived for centuries to understand the principles governing those complex mechanical phenomena, providing a number of continuous models for slender structures, granular matter, and frictional contact. In the XX${}^{\mathrm{th}}$ century, industrial applications such as process automatization and new ways of transportation have boosted the fields of Mechanical Engineering and Computer-Aided Design, where material strength, reliability of mechanisms, and safety, standed for the main priorities. Instead, large displacements of structures, buckling, tearing, or entanglement, and even dynamics, were long considered as undesirable behaviors, thus restraining the search for corresponding numerical models.

Only recently, the engineering industry has shown some new and growing interest into the modeling of dynamic phenomena prone to large displacements, contact and friction. For instance, the cosmetology industry is more and more interested in understanding the nonlinear deformation of hair and skin, with the help of simulation. Likewise, auto and aircraft manufacturers are facing new challenges involving buckling or entanglement of thin structures such as carbon or optical fibers; they clearly lack predictive, robust and efficient numerical tools for simulating and optimizing their new manufacturing process, which share many common features with the large-scale simulation scenarii traditionally studied in Computer Graphics applications.

4.2 Computer Graphics

In contrast, Computer Graphics, which has emerged in the 60's with the advent of modern computers, was from the very beginning eager to capture such peculiar phenomena, with the sole aim to produce spectacular images and create astonishing stories. At the origin, Computer Graphics thus drastically departed from other scientific fields. Everyday-life phenomena such as cloth buckling, paper tearing, or hair fluttering in the wind, mostly ignored by other scientists at that time, became actual topics of interest, involving a large set of new research directions to be explored, both in terms of modelling and simulation. Nowadays, although the image production still remains the core activity of the Computer Graphics community, more and more research studies are directed through the virtual and real prototyping of mechanical systems, notably driven by a myriad of new applications in the virtual try on industry (e.g., hairstyling and garment fitting). Furthermore, the advent of additive fabrication is currently boosting research in the free design of new mechanisms or systems for various applications, from architecture design and fabrication of metamaterials to the creation of new locomotion modes in robotics. Some obvious common interests and approaches are thus emerging between Computer Graphics and Mechanical Engineering, yet the two communities remain desperately compartmentalized.

4.3 Soft Matter Physics

From the physics-based viewpoint, since a few decades a new generation of physicists became interested again in the understanding of such visually fascinating phenomena, and started investigating the tight links between geometry and elasticity 2. Common objects such as folded or torn paper, twined plants, coiled honey threads, or human hair have thus regained some popularity among the community in Nonlinear Physics 3. In consequence, phenomena of interest have become remarkably close to those of Computer Graphics, since scientists in both places share the common goal to model complex and integrated mechanical phenomena at the macroscopic scale. Of course, the goals and employed methodologies differ substantially from one community to the other, but showcase some evident complementarity: while computer scientists are eager to learn and understand new physical models, physicists get more and more interested in the numerical tools, in which they perceive not only a means to confirm predictions afterwards, but also a support for testing new hypothesis and exploring scenarios that would be too cumbersome or even impossible to investigate experimentally. Besides, numerical exploration starts becoming a valuable tool for getting insights into the search for analytic solutions, thus fully participating to the modeling stage and physical understanding. However, physicists may be limited to a blind usage of numerical black boxes, which may furthermore not be dedicated to their specific needs. According to us, promoting a science of modeling in numerical physics would thus be a promising and rich avenue for the two research fields. Unfortunately, very scarce cooperation currently exists between the two communities, and large networks of collaboration still need to be set up.

5.1 Footprint of research activities

The Elan team is environment-sensitive. Since its creation in 2017, 100% of its research staff moves daily from home to the lab using soft transportation means (biking, public transportation). Intercontinental missions are limited while train is the preferred mode of transportation in Europe.

5.2 Impact of research results

A large part of the research conducted in the team is of fundamental level. Direct applications lie in numerical arts, cloth design, sports, and environmental studies, all of these being of limited negative impact for the environment. Collaborations with industry leading specially harmful activities to the environment are avoided.

6.1 New software

7.1 Static simulation of thin elastic ribbons

Participant: Raphaël Charrondière, Florence Bertails-Descoubes, Victor Romero.

7.2 Video-based measurement of the friction coefficient between cloth and a substrate

Participant: Haroon Rasheed, Victor Romero, Florence Bertails-Descoubes.

7.3 Willmore flow simulation with diffusion-redistanciation numerical schemes

Participant: Thibaut Metivet.

7.4 Fast frictional contact solver

Participant: Mickaël Ly, Jean Jouve, Laurence Boissieux, Florence Bertails-Descoubes.

7.5 Validation of simulators for slender elastic structures and frictional contact

Participant: Victor Romero, Mickaël Ly, Haroon Rasheed, Raphaël Charrondière, Florence Bertails-Descoubes.

In collaboration with Arnaud Lazarus and Sébastien Neukirch (Sorbonne Université, Institut Jean le Rond d'Alembert), we have set up a new framework for validating simulators of slender elastic structures (rods and plates) and frictional contact. To this aim we leverage and enrich a set of protocols from the Soft Matter Physics community, initially devised for measuring elasticity and frictional properties of slender elastic structures. These retained tests, that we experimentally validate, are characterized by scaling laws which only depend on a few dimensionless parameters, making them ideal for benchmarking robustly a large diversity of codes across different physical regimes, without having to worry about scales or dimensions. We have passed a number of popular codes of Computer Graphics through our benchmarks by defining a rigorous, consistent, and as fair as possible methodology. Our results show that while some popular simulators for plates/shells and frictional contact fail even on the simplest scenarios, more recent ones, as well as well-known codes for rods, generally perform well and sometimes even better than some reference commercial tools of Mechanical Engineering. Our benchmarking study has been conditionally accepted for publication at ACM SIGGRAPH 2021.

8.1 European initiatives

8.2 National initiatives

9.1 Promoting scientific activities

9.2 Teaching - Supervision - Juries

9.3 Popularization

10.1 Major publications

• 1 articleFlorenceF. Bertails-Descoubes, AlexandreA. Derouet-Jourdan, VictorV. Romero and ArnaudA. Lazarus. Inverse design of an isotropic suspended Kirchhoff rod: theoretical and numerical results on the uniqueness of the natural shapeProceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences4742212April 2018, 1-26
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• 2 articleJieJ. Li, GillesG. Daviet, RahulR. Narain, FlorenceF. Bertails-Descoubes, MatthewM. Overby, GeorgeG. Brown and LaurenceL. Boissieux. An Implicit Frictional Contact Solver for Adaptive Cloth SimulationACM Transactions on Graphics374August 2018, 1-15
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• 3 articleMickaëlM. Ly, RomainR. Casati, FlorenceF. Bertails-Descoubes, MélinaM. Skouras and LaurenceL. Boissieux. Inverse Elastic Shell Design with Contact and FrictionACM Transactions on Graphics376November 2018, 1-16
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10.2 Publications of the year

10.3 Cited publications

• 8 articleB. Audoly and S. Neukirch. Fragmentation of Rods by Cascading Cracks: Why Spaghetti Does Not Break in HalfPhysical Review Letters9592005, 095505
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• 9 inproceedingsD. Baraff. Analytical methods for dynamic simulation of non-penetrating rigid bodiesComputer Graphics Proceedings (Proc. ACM SIGGRAPH'89 )New York, NY, USAACM1989, 223--232
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• 10 articleF. Bertails, B. Audoly, M.-P. Cani, B. Querleux, F. Leroy and J.-L. Lévêque. Super-Helices for Predicting the Dynamics of Natural HairACM Transactions on Graphics (Proc. ACM SIGGRAPH'06)2532006, 1180--1187URL: http://www-evasion.imag.fr/Publications/2006/BACQLL06
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• 11 articleF. Bertails. Linear Time Super-HelicesComputer Graphics Forum (Proc. Eurographics'09)282apr 2009, URL: http://www-ljk.imag.fr/Publications/Basilic/com.lmc.publi.PUBLI_Article@1203901df78_1d3cdaa/
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• 12 articleF. Bertails-Descoubes. Super-ClothoidsComputer Graphics Forum (Proc. Eurographics'12)312pt22012, 509--518URL: http://www.inrialpes.fr/bipop/people/bertails/Papiers/superClothoids.html
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• 13 inproceedings AlejandroA. Blumentals, FlorenceF. Bertails-Descoubes and RomainR. Casati. Dynamics of a developable shell with uniform curvatures The 4th Joint International Conference on Multibody System Dynamics Montréal, Canada May 2016
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• 14 phdthesis AlejandroA. Blumentals. Numerical modelling of thin elastic solids in contact Université de Grenoble Alpes July 2017
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• 15 articleSofienS. Bouaziz, SebastianS. Martin, TiantianT. Liu, LadislavL. Kavan and MarkM. Pauly. Projective Dynamics: Fusing Constraint Projections for Fast SimulationACM Trans. Graph.334July 2014, 154:1--154:11URL: http://doi.acm.org/10.1145/2601097.2601116
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• 16 articleR. Casati and F. Bertails-Descoubes. Super Space ClothoidsACM Transactions on Graphics (Proc. ACM SIGGRAPH'13)324July 2013, 48:1--48:12URL: http://doi.acm.org/10.1145/2461912.2461962
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• 17 bookDominiqueD. Chapelle and K.J.K. Bathe. The Finite Element Analysis of Shells - Fundamentals - Second EditionComputational Fluid and Solid MechanicsSpringer2011, 410
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• 18 inproceedingsP. Cundall. A computer model for simulating progressive large scale movements of blocky rock systems. In Proceedings of the Symposium of the International Society of Rock MechanicsProceedings of the Symposium of the International Society of Rock Mechanics11971, 132--150
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• 19 articleGillesG. Daviet and FlorenceF. Bertails-Descoubes. A semi-implicit material point method for the continuum simulation of granular materialsACM Transactions on Graphics354July 2016, 13
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• 20 articleG. Daviet, F. Bertails-Descoubes and L. Boissieux. A hybrid iterative solver for robustly capturing Coulomb friction in hair dynamicsACM Transactions on Graphics (Proc. ACM SIGGRAPH Asia'11)3062011, 139:1--139:12URL: http://www.inrialpes.fr/bipop/people/bertails/Papiers/hybridIterativeSolverHairDynamicsSiggraphAsia2011.html
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• 21 articleGillesG. Daviet and FlorenceF. Bertails-Descoubes. Nonsmooth simulation of dense granular flows with pressure-dependent yield stressJournal of Non-Newtonian Fluid Mechanics234April 2016, 15-35
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• 22 unpublishedGillesG. Daviet and FlorenceF. Bertails-Descoubes. Simulation of Drucker--Prager granular flows inside Newtonian fluidsFebruary 2017, working paper or preprint
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• 23 phdthesis G. Daviet. Modèles et algorithmes pour la simulation du contact frottant dans les matériaux complexes : application aux milieux fibreux et granulaires Grenoble Alpes Universités December 2016
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• 24 articleA. Derouet-Jourdan, F. Bertails-Descoubes, G. Daviet and J. Thollot. Inverse Dynamic Hair Modeling with Frictional ContactACM Trans. Graph.326November 2013, 159:1--159:10URL: http://doi.acm.org/10.1145/2508363.2508398
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• 25 articleA. Derouet-Jourdan, F. Bertails-Descoubes and J. Thollot. Stable Inverse Dynamic CurvesACM Transactions on Graphics (Proc. ACM SIGGRAPH Asia'10 )296December 2010, 137:1--137:10URL: http://doi.acm.org/10.1145/1882261.1866159
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• 26 articleMarcelo A.M. Dias and BasileB. Audoly. ``Wunderlich, Meet Kirchhoff'': A General and Unified Description of Elastic Ribbons and Thin RodsJournal of Elasticity1191Apr 2015, 49--66URL: https://doi.org/10.1007/s10659-014-9487-0
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• 27 manual E. J.E. Doedel, R. C.R. Pfaffenroth, A. R.A. Chambodut, T. F.T. Fairgrieve, Y. A.Y. Kuznetsov, B. E.B. Oldeman, B. Sandstede and X. Wang. AUTO 2000: Continuation and Bifurcation Software for Ordinary Differential Equations (with HomCont) March 2006
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• 28 miscESPCI. Rencontre en l'honneur de Yves Pomeau, octobre 2016https://www.sfpnet.fr/rencontre-celebrant-la-medaille-boltzmann-d-yves-pomeauESPCI2016, URL: https://www.sfpnet.fr/rencontre-celebrant-la-medaille-boltzmann-d-yves-pomeau
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• 29 articleI.A.I. Frigaard and C. Nouar. On the usage of viscosity regularisation methods for visco-plastic fluid flow computationJournal of Non-Newtonian Fluid Mechanics1271April 2005, 1--26
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• 30 book A. L.A. Gol'Denveizer. Theory of Elastic Thin Shells Pergamon Press 1961
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• 31 articleRaymond E.R. Goldstein, Patrick B.P. Warren and Robin C.R. Ball. Shape of a Ponytail and the Statistical Physics of Hair Fiber BundlesPhys. Rev. Lett.1087Feb 2012, 078101URL: https://link.aps.org/doi/10.1103/PhysRevLett.108.078101
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• 32 articleM. Jean. The Non Smooth Contact Dynamics MethodComputer Methods in Applied Mechanics and Engineering177Special issue on computational modeling of contact and friction, J.A.C. Martins and A. Klarbring, editors1999, 235-257
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• 33 article J. Li, G. Daviet, R. Narain, F. Bertails-Descoubes, M. Overby, G. Brown and L. Boissieux. An Implicit Frictional Contact Solver for Adaptive Cloth Simulation ACM Trans. Graph. 37 4 August 2018
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• 34 inproceedingsM. Moore and J. Wilhelms. Collision detection and response for computer animationComputer Graphics Proceedings (Proc. ACM SIGGRAPH'88 )1988, 289--298
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• 35 articleD. Moulton, P. Grandgeorge and S. Neukirch. Stable elastic knots with no self-contactJournal of the Mechanics and Physics of Solids1162018, 33--53URL: http://www.sciencedirect.com/science/article/pii/S0022509617310104
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• 36 article J. Spillmann and M. Teschner. An Adaptive Contact Model for the Robust Simulation of Knots Computer Graphics Forum 27 2 Proc. Eurographics'08 2008
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• 37 article H. Sugiyama, J. Gertsmayr and A. Mikkola. Flexible Multibody Dynamics — Essential for Accurate Modeling in Multibody System Dynamics Journal of Computational Nonlinear Dynamics 9 1 Novembler 2013
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