Your search keyword '"Doškář, M."' showing total 9 results

1. Microstructure-informed reduced modes synthesized with Wang tiles and the Generalized Finite Element Method

Author

Doškář, M., Zeman, J., Krysl, P., and Novák, J.

Subjects

Condensed Matter - Materials Science, Computer Science - Computational Engineering, Finance, and Science, Physics - Computational Physics

Abstract

A recently introduced representation by a set of Wang tiles -- a generalization of the traditional Periodic Unit Cell based approach -- serves as a reduced geometrical model for materials with stochastic heterogeneous microstructure, enabling an efficient synthesis of microstructural realizations. To facilitate macroscopic analyses with a fully resolved microstructure generated with Wang tiles, we develop a reduced order modelling scheme utilizing pre-computed characteristic features of the tiles. In the offline phase, inspired by the computational homogenization, we extract continuous fluctuation fields from the compressed microstructural representation as responses to generalized loading represented by the first- and second-order macroscopic gradients. In the online phase, using the ansatz of the Generalized Finite Element Method, we combine these fields with a coarse finite element discretization to create microstructure-informed reduced modes specific for a given macroscopic problem. Considering a two-dimensional scalar elliptic problem, we demonstrate that our scheme delivers less than a 3% error in both the relative $L_2$ and energy norms with only 0.01% of the unknowns when compared to the fully resolved problem. Accuracy can be further improved by locally refining the macroscopic discretization and/or employing more pre-computed fluctuation fields. Finally, unlike the standard snapshot-based reduced-order approaches, our scheme handles significant changes in the macroscopic geometry or loading without the need for recalculating the offline phase, because the fluctuation fields are extracted without any prior knowledge on the macroscopic problem., Comment: 17 pages, 14 figures

Published

2020

2. A Newton Solver for Micromorphic Computational Homogenization Enabling Multiscale Buckling Analysis of Pattern-Transforming Metamaterials

Author

van Bree, S. E. H. M., Rokoš, O., Peerlings, R. H. J., Doškář, M., and Geers, M. G. D.

Subjects

Computer Science - Computational Engineering, Finance, and Science, Condensed Matter - Soft Condensed Matter

Abstract

Mechanical metamaterials feature engineered microstructures designed to exhibit exotic, and often counter-intuitive, effective behaviour. Such a behaviour is often achieved through instability-induced transformations of the underlying periodic microstructure into one or multiple patterning modes. Due to a strong kinematic coupling of individual repeating microstructural cells, non-local behaviour and size effects emerge, which cannot easily be captured by classical homogenization schemes. In addition, the individual patterning modes can mutually interact in space as well as in time, while at the engineering scale the entire structure can buckle globally. For efficient numerical macroscale predictions, a micromorphic computational homogenization scheme has recently been developed. Although this framework is in principle capable of accounting for spatial and temporal interactions between individual patterning modes, its implementation relied on a gradient-based quasi-Newton solution technique. This solver is suboptimal because (i) it has sub-quadratic convergence, and (ii) the absence of Hessians does not allow for proper bifurcation analyses. Given that mechanical metamaterials often rely on controlled instabilities, these limitations are serious. To address them, a full Newton method is provided in detail in this paper. The construction of the macroscopic tangent operator is not straightforward due to specific model assumptions on the decomposition of the underlying displacement field pertinent to the micromorphic framework, involving orthogonality constraints. Analytical expressions for the first and second variation of the total potential energy are given, and the complete algorithm is listed. The developed methodology is demonstrated with two examples in which a competition between local and global buckling exists and where multiple patterning modes emerge., Comment: 34 pages, 17 figures, 1 table, 1 algorithm, abstract shortened to fulfill 1920 character limit

Published

2020

3. A jigsaw puzzle metamaterial concept

Author

Nežerka, V., Somr, M., Janda, T., Vorel, J., Doškář, M., Antoš, J., Zeman, J., and Novák, J.

Subjects

Condensed Matter - Materials Science

Abstract

A concept of a planar modular mechanical metamaterial inspired by the nature's principle of local adaptivity is proposed. The metamaterial consists of identical pieces similar to jigsaw puzzle tiles. Their rotation within assembly provides a substantial flexibility in terms of structural behavior and mechanical interlocks enable reassembly. The tile design with a diagonal elliptical opening allows us to vary elastic properties--from stiff to compliant, with positive, zero, or negative Poisson's ratio. The outcomes of experimental testing on additively manufactured specimens confirm that the assembly properties can be accurately designed using optimization approaches with finite element analysis at heart., Comment: 9 pages, 8 figures

Published

2018

4. A Newton solver for micromorphic computational homogenization enabling multiscale buckling analysis of pattern-transforming metamaterials

Author

van Bree, S.E.H.M., primary, Rokoš, O., additional, Peerlings, R.H.J., additional, Doškář, M., additional, and Geers, M.G.D., additional

Published

2020

5. Local tilings informed synthesis of micro-mechanical fields by means of Wang tiles

Author

Zrůbek, L., Doškář, M., Kučerová, A., Adámek, Vítězslav, Jonášová, Alena, Plánička, Stanislav, and Zajíček, Martin

Subjects

Wang tiles, algorithm, statistically equivalent periodic unit cell method, Wangovo dláždění, statisticky ekvivalentní metoda periodických jednotkových buněk, synthesis of micro-mechanical fields, algoritmus, syntéza mikromechanických polí

Abstract

Grant Agency of the CTU in Prague, the grant No. SGS19/033/OHK1/1T/11 - Design toolchain for modular structures: Accelerated optimization and stochastic analysis

Published

2019

6. Wang tiles and metal foam micro-structure image synthesis

Author

Zrůbek, L., Doškář, M., Kučerová, A., Meneses-Guzmán, M., Rodríguez-Méndez, F., Adámek, Vítězslav, Jonášová, Alena, Plánička, Stanislav, and Zajíček, Martin

Subjects

syntéza obrazu, metoda Wangových dlaždic, image synthesis, kovovopěnová mikrostruktura, metal foam micro-structure, Wang tiles method

Abstract

The authors gratefully acknowledge the financial support from the Grant Agency of the CTU in Prague, the grant No. SGS18/036/OHK1/1T/11 (L. Zr°ubek, M. Doˇsk´aˇr and A. Kuˇcerov´a). Authors would also like to thank for the support from Vicerrector´ıa de Investigaci´on y Extensi´on, project No. 1351022 (M. Meneses-Guzm´an, F. Rodr´ıguez-M´endez and B. Chin´e). Our latest work is focused on image synthesis of metal foam micro-structures using the Wang tiles and Automatic tile design.

Published

2018

7. A jigsaw puzzle metamaterial concept

Author

Nežerka, V., primary, Somr, M., additional, Janda, T., additional, Vorel, J., additional, Doškář, M., additional, Antoš, J., additional, Zeman, J., additional, and Novák, J., additional

Published

2018

8. Modification of the quadratic 10-node tetrahedron for thin structures and stiff materials under large-strain hyperelastic deformation

Author

Nguyen, P., primary, Doškář, M., additional, Pakravan, A., additional, and Krysl, P., additional

Published

2018

9. Aperiodic compression and reconstruction of real-world material systems based on Wang tiles.

Author

Doškář M, Novák J, and Zeman J

Abstract

The paper presents a concept to compress and synthesize complex material morphologies that is based on Wang tilings. Specifically, a microstructure is stored in a set of Wang tiles and its reconstruction is performed by means of a stochastic tiling algorithm. A substantial part of the study is devoted to the setup of optimal parameters of the automatic tile design by means of parametric studies with statistical descriptors at heart. The performance of the method is demonstrated on four two-dimensional two-phase target systems, monodisperse media with hard and soft disks, sandstone, and high porosity metallic foam.

Published

2014