17 results on '"Eliáš, Jan"'
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2. Influence of inertia and material properties on discrete simulation of dynamic fracture of concrete
- Author
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Květoň, Josef and EliáŠ, Jan
- Published
- 2018
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3. Elastic properties of isotropic discrete systems: Connections between geometric structure and Poisson's ratio.
- Author
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Eliáš, Jan
- Subjects
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ISOTROPIC properties , *ELASTICITY , *GEOMETRIC connections , *DISCRETE systems , *LARGE deviation theory - Abstract
• Elastic behavior of isotropic discrete models with an arbitrary geometry is analyzed. • An analytical estimation of the macroscopic elastic characteristics is derived. • It is shown that the widest limits of the Poisson's ratio are obtained for Voronoi and Power tessellation. • The Poisson's ratio limits cannot be further extended by manipulations with the model geometry. The use of discrete material representation in numerical models is advantageous due to the straightforward way it takes into account material heterogeneity and randomness, and the discrete and orientated nature of cracks. Unfortunately, it also restricts the macroscopic Poisson's ratio and therefore narrows its applicability. The paper studies the Poisson's ratio of a discrete model analytically. It derives theoretical limits for cases where the geometry of the model is completely arbitrary, but isotropic in the statistical sense. It is shown that the widest limits are obtained for models where normal directions of contacts between discrete units are parallel with the vectors connecting these units. Any deviation from parallelism causes the Poisson's ratio limits to shrink. A comparison of the derived equations to the results of the actual numerical model is presented. It shows relatively large deviations from the theory because the fundamental assumptions behind the theoretical derivations are largely violated in systems with complex geometry. The real shrinking of the Poisson's ratio limit is less severe compared to that which is theoretically derived. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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4. Adaptive technique for discrete models of fracture.
- Author
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Eliáš, Jan
- Subjects
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BRITTLE material fracture , *INHOMOGENEOUS materials , *DISCRETE geometry , *DISCRETIZATION methods , *PROBABILITY theory , *SIMULATION methods & models - Abstract
Static discrete models are advantageously used for the simulation of fracture in quasibrittle heterogeneous materials. In order to correctly capture strain localization during the fracture process, it is often necessary to represent material heterogeneity in the model directly via its discrete geometry. Depending on the specimen size and the size of the heterogeneities, these simulations are typically extremely computationally demanding. The contribution aims to reduce this computational cost via the implementation of adaptivity in the construction of the discrete model geometry. The simulation starts with coarse discretization, which provides correct elastic behavior and is then adaptively refined during the simulation in regions that suffer high stresses that induce cracking and strain localization. The technique is applied in deterministic and probabilistic simulations and demonstrated on several examples. [ABSTRACT FROM AUTHOR]
- Published
- 2016
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5. Modification of the Audze–Eglājs criterion to achieve a uniform distribution of sampling points.
- Author
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Eliáš, Jan and Vořechovský, Miroslav
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UNIFORM distribution (Probability theory) , *HYPERCUBES , *BOUNDARY value problems , *STATISTICAL sampling , *RANDOM variables , *COMBINATORIAL optimization - Abstract
The Audze–Eglājs (AE) criterion was developed to achieve a uniform distribution of experimental points in a hypercube. However, the paper shows that the AE criterion provides strongly nonuniform designs due to the effect of the boundaries of the hypercube. We propose a simple remedy that lies in the assumption of periodic boundary conditions. The biased behavior of the original AE criterion and excellent performance of the modified criterion are demonstrated using simple numerical examples focused on (i) the uniformity of sampling density over the design space and, (ii) statistical sampling efficiency measured through the ability to correctly estimate the statistical parameters of functions of random variables. An engineering example of reliability calculation is presented, too. [ABSTRACT FROM AUTHOR]
- Published
- 2016
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6. Stochastic discrete meso-scale simulations of concrete fracture: Comparison to experimental data.
- Author
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Eliáš, Jan, Vořechovský, Miroslav, Skoček, Jan, and Bažant, Zdeněk P.
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CONCRETE fractures , *STOCHASTIC processes , *SPATIAL variation , *PARAMETER estimation , *ENERGY dissipation - Abstract
The paper presents a discrete meso-scale model for fracture of concrete taking into account random spatial variability of material parameters. Beams of various sizes, with notches of various depths, are simulated numerically to study the combination of energetic and statistical size effects. A substantial part of material randomness is shown to be caused by random locations of the largest aggregates. Further randomness, due to random fluctuations of material parameters, is considered and an effect of introducing a spatially auto-correlated random field is analyzed. The results of the simulations are compared with recently published experimental data on concrete beams in three-point bending. The differences in the role of randomness in beams of various sizes, with different notch depths, are demonstrated, and differences in energy dissipation are discussed. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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7. Shape optimization of concrete buried arches
- Author
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Houšt’, Vladimír, Eliáš, Jan, and Miča, Lumír
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STRAINS & stresses (Mechanics) , *CONCRETE , *BENDING (Metalwork) , *FLEXURAL strength , *FINITE element method , *SOIL compaction , *MATHEMATICAL optimization , *NUMERICAL analysis - Abstract
Abstract: Shape optimization in connection with numerical modelling is used to reduce bending and associated flexural stresses in buried concrete arches. Modelling of the arch is carried out via a nonlinear finite element model that accounts for soil constitutive relations, soil–structure interactions, sequential construction stages and soil compaction. Centre line of the arch is parameterized by Bézier curve with three degrees of freedom that are subjected to optimization by genetic and Levenberg–Marquardt algorithm. The paper presents a parametric study which aims to determine the optimal shapes for buried arches of various span/rise ratios, backfill depths and foundation soil types. In the second part of the paper it shows a theoretical reduction in tensile stresses obtained by shape optimization of concrete arch culvert with a 9.4m span tested at the University of Massachusetts at Amherst. [Copyright &y& Elsevier]
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- 2013
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8. Modeling of mode-I fatigue crack growth in quasibrittle structures under cyclic compression
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Eliáš, Jan and Le, Jia-Liang
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MATHEMATICAL models , *FATIGUE crack growth , *BRITTLENESS , *STRUCTURAL analysis (Engineering) , *MATERIALS compression testing , *TENSILE tests , *FRACTURE mechanics - Abstract
Abstract: A cyclic cohesive zone model is proposed to simulate the mode-I crack growth in quasibrittle structures under compressive fatigue. The constitutive behavior of the cohesive elements is formulated for both tension and compression regimes. A strain-softening cohesive law is adopted for the tension regime whereas a plastic-type cohesive behavior is considered for the compression regime. It is shown that the proposed model is able to capture some essential fracture behaviors of quasibrittle structures under compressive fatigue, which include the onset of fatigue crack growth, the gradual decrease in crack growth rate, and the exhaustion of residual tensile stress over the cycles. Based on a fracture process zone (FPZ)-equivalence principle, it is further shown that the existing kinetics equation for tensile fatigue crack can be extended to the crack growth under cyclic compression. [Copyright &y& Elsevier]
- Published
- 2012
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9. Improved sequentially linear solution procedure
- Author
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Eliáš, Jan, Frantík, Petr, and Vořechovský, Miroslav
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SEQUENTIAL analysis , *FRACTURE mechanics , *SIMULATION methods & models , *MECHANICAL behavior of materials , *MECHANICAL loads , *STRESS concentration , *BRITTLENESS - Abstract
Abstract: The article proposes an improvement over the widely used sequentially linear solution procedure often utilized for fracture simulations. In the classical secant version of this method, a partial solution of a step is scaled to reach a stress limit in exactly one element and the mechanical properties of the critical element are reduced. Non-proportional loading is generally unfeasible due to avalanches of ruptures caused by stress redistribution. Because only one loading vector can be scaled at a time, all others have to remain constant during the step. However, the constant load vectors do not allow proper determination of the critical element. A modified procedure based on redistribution of released stresses is developed here. It preserves the linearity of each step. After rupture of the critical element, a sequentially linear redistribution process of stress release takes place until a static equilibrium state is reached. During the redistribution, other elements may break. The proposed enhanced sequential procedure is also compared with another recently published “event-by-event” linear method for non-proportional loading. It is shown here, with the help of simple examples, that the proposed redistribution method yields correct results for non-proportional loading, unlike the other methods under comparison. [Copyright &y& Elsevier]
- Published
- 2010
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10. Discrete mechanical models of concrete fracture.
- Author
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Bolander, John E., Eliáš, Jan, Cusatis, Gianluca, and Nagai, Kohei
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CONCRETE fractures , *MECHANICAL models , *POISSON'S ratio , *INHOMOGENEOUS materials - Abstract
Discrete models of solids have been motivated, in large part, by the discontinuous and heterogeneous nature of material structure and its breakdown under loading. The capabilities of discrete models have evolved over the past several decades, offering novel means for investigating material structure–property relationships. However, lack of understanding of both the utilities and disadvantages of discrete models limits their further development and applications. This paper reviews relevant features of discrete approaches applied to modeling the mechanical behavior of geomaterials, concrete materials in particular. The discrete models are classified according to their form and abilities to represent elastic and fracture behaviors in the presence of large-scale material heterogeneity. Discretization of the material domain plays a large role in this respect. Emphasis is placed on particle-based lattice models. The relative merits of various strategies for introducing reinforcing components, which are essential for many applications, are outlined. Recent advances are highlighted, including the use of discrete models for coupled, multi-field analysis. The merits of discrete approaches are summarized in the conclusions. • Discrete methods for simulating concrete fracture are critiqued. • Model capabilities depend on the choice of physical or non-physical forms of discretization. • The topics of stress oscillation, Poisson's ratio and volumetric effects are examined. • Dual-lattice models are suited to modeling hygro-mechanical couplings in cracked media. • Application examples demonstrate the utilities and expanding use of discrete methods. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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11. Periodic version of the minimax distance criterion for Monte Carlo integration.
- Author
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Eliáš, Jan, Vořechovský, Miroslav, and Sadílek, Václav
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MONTE Carlo method , *COMPUTER engineering , *DESIGN exhibitions , *ALGORITHMS , *CHEBYSHEV approximation , *ENGINEERING mathematics , *LATIN hypercube sampling , *ENGINEERING standards , *NUMERICAL integration - Abstract
• numerical integration with designs optimized via miniMax (mM) criterion is developed. • mM designs with standard metric are nonuniform which may cause biased integration. • the proposed periodic metric ensures point uniformity and unbiased robust integration. • efficient construction algorithm for mM designs (standard or periodic) is developed. The selection of points for numerical integration of the Monte Carlo type, largely used in analysis of engineering problems, is developed. It is achieved by modification of the metric in the minimax optimality criterion. The standard minimax criterion ensures the design exhibits good space-filling property and therefore reduces the variance of the estimator of the integral. We, however, show that the points are not selected with the same probability over the space of sampling probabilities: some regions are over- or under-sampled when designs are generated repetitively. This violation of statistical uniformity may lead to systematically biased integral estimators. We propose that periodic metric be considered for calculation of the minimax distance. Such periodic minimax criterion provides statistically uniform designs leading to unbiased integration results and also low estimator variance due to retained space-filling property. These conclusions are demonstrated by examples integrating analytical functions. The designs are constructed by two different algorithms: (i) a new time-stepping algorithm resembling a damped system of attracted particles developed here, and (ii) the heuristic swapping of coordinates. The designs constructed by the time-stepping algorithm are attached to the paper as a supplementary material. The computer code for construction of the designs is attached too. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
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12. Fracture in random quasibrittle media: I. Discrete mesoscale simulations of load capacity and fracture process zone.
- Author
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Eliáš, Jan and Vořechovský, Miroslav
- Subjects
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RANDOM fields , *PEAK load , *CONCRETE fractures , *TENSION loads , *ZONING - Abstract
• Mesoscale discrete model of concrete enhanced by spatially random material parameters. • Notched and unnotched three point bending and uniaxial tension are analyzed. • Fracture process zone statistically evaluated for various random field parameters. • Nontrivial dependence of peak loads on correlation length and variance is reported. • Local averaging and weakest-link are identified as the underlying mechanisms. Numerical simulations of concrete fracture performed with a probabilistic mesoscale discrete model are presented. The model represents a substantial part of material randomness by assigning random locations to the largest aggregates. The remaining part of randomness is introduced by causing material parameters to fluctuate randomly via a homogeneous random field. An extensive numerical study performed with the model considers prisms loaded in uniaxial tension with both fixed and rotating platens, and also beams with and without a notch loaded in three point bending. The results show the nontrivial effect of (i) autocorrelation length and (ii) variance of the random field on the fracture behavior of the model. Statistics of the peak load are presented as well as the size and shape of the fracture process zone at the moment when the maximum load is attained. Local averaging within the fracture process zone and weakest-link are identified as underlying mechanisms explaining the reported results. The companion paper, Part II (Vořechovský and Eliáš, 2020), introduces an analytical model capable of predicting the distribution of the peak load obtained with the probabilistic discrete model via the simple estimation of extremes of a random field obtained as moving average of local strength. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
13. Fracture in random quasibrittle media: II. Analytical model based on extremes of the averaging process.
- Author
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Vořechovský, Miroslav and Eliáš, Jan
- Subjects
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RANDOM fields , *CONCRETE fractures , *CONCRETE beams , *PEAK load , *GAUSSIAN distribution , *EXTREME value theory , *BRITTLE materials , *WEIBULL distribution - Abstract
• Strength prediction of quasibrittle material that removes problems of Weibull theory. • Statistics of peak load are obtained analytically based on extremes of local averages. • Local averaging of Gaussian random field provides effective strength of material. • The weakest-link mechanics is incorporated via extremes of effective strength field. • Four model parameters are used to represent a wide range of random field parameters. The paper delivers an analytical model for prediction of the peak force in concrete specimens loaded in bending (both notched and unnotched). The model is capable of predicting peak force statistics by computing the extreme values of sliding averages of random strength fields. The local strength of the specimen is modeled by a stationary isotropic random field with Gaussian distribution and a given autocorrelation function. The averaging operation represents the progressive loss in material integrity and the associated stress redistribution that takes place prior to reaching the peak load. Once the (linear) averaging process is performed analytically, the resulting random field of averaged strength is assumed to represent a series of representative volume elements (RVEs) and the global strength is found by solving for the minimum of such an effective strength field. All these operations can be written analytically and there are only four model parameters: the three dimensions of the averaging volume (RVE) and the length of the final weakest-link chain. The model is verified using detailed numerical computations of notched and unnotched concrete beams simulated by mesoscale discrete simulations of concrete fracture performed with probabilistic distributions of model parameters. These are presented in the companion paper Part I (Eliáš and Vořechovský, 2020). The numerical model used for verification represents material randomness both by assigning random locations to the largest aggregates and by simulating random fluctuations of material parameters via a homogeneous random field. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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14. Distance-based optimal sampling in a hypercube: Analogies to N-body systems.
- Author
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Vořechovský, Miroslav, Mašek, Jan, and Eliáš, Jan
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EQUATIONS of motion , *HYPERCUBES , *DYNAMICAL systems , *NUMERICAL integration , *PARTICLE motion , *RELIABILITY in engineering - Abstract
• Uniform distribution of points in a unit hypercube. • Optimal Design of Experiments for computationally intensive models. • The analogy to a dynamical system of repulsive particles in periodic space is exploited. A method is proposed for the construction of uniformly distributed point sets within a design domain using an analogy to a dynamical system of interacting particles. The possibility of viewing various distance-based optimality criteria as formulas representing the potential energy of a system of charged particles is discussed. The potential energy is employed in deriving the equations of motion of the particles. The particles are either attracted or repelled and dissipative dynamical systems can be simulated to achieve optimal and near-optimal arrangements of points. The design domain is set up as an N var -dimensional unit hypercube, with N var being the number of variables (factors). The number of points is equal to the number of simulations (levels). The periodicity assumption of the design domain is shown to be an elegant way to obtain statistically uniform coverage of the design domain. The ϕ p criterion, which is a generalization of the Maximin criterion, is selected in order to demonstrate its analogy with an N-body system. This criterion guarantees that the points are spread uniformly within the design domain. The solution to such an N-body system is presented. The obtained designs are shown to outperform the existing optimal designs in various types of applications: multidimensional numerical integration, statistical exploration of computer models, reliability analyses of engineering systems, and screenings or exploratory designs for the global optimization/minimization of functions. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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15. Metabolic rewiring in a cellular model lacking ATP synthase.
- Author
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Puertas-Frias, Guillermo, Čunátová, Kristýna, Pecina, Petr, Vrbacký, Marek, Eliáš, Jan, Houštěk, Josef, Mráček, Tomáš, and Pecinová, Alena
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ADENOSINE triphosphatase - Published
- 2022
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16. Searching for function of TMEM70, TMEM242 and c15orf61 – recently identified interactors of subunit c from mammalian FoF1 ATP synthase.
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Marković, Aleksandra, Vrbacký, Marek, Pecina, Petr, Eliáš, Jan, Koňaříková, Eliška, Houštěk, Josef, and Mráček, Tomáš
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ADENOSINE triphosphatase - Published
- 2022
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17. Uncovering the OXPHOS complexes' interdependence mechanism.
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Čunátová, Kristýna, Vrbacký, Marek, Puertas-Frias, Guillermo, Eliáš, Jan, Houštěk, Josef, Pecinová, Alena, Pecina, Petr, and Mráček, Tomáš
- Published
- 2022
- Full Text
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