| 020 | $a9783030307059 |
| 082 | $a515.353 |
| 099 | $aOnline resource: Springer |
| 245 | $aNumerical Methods for Flows$h[EBook]$bFEF 2017 Selected Contributions /$cedited by Harald van Brummelen, Alessandro Corsini, Simona Perotto, Gianluigi Rozza. |
| 250 | $a1st ed. 2020. |
| 260 | $aCham :$bSpringer International Publishing :$bImprint: Springer,$c2020. |
| 300 | $aXII, 362 p. 186 illus., 81 illus. in color.$bonline resource. |
| 336 | $atext |
| 338 | $aonline resource |
| 440 | $aLecture Notes in Computational Science and Engineering,$x1439-7358 ;$v132 |
| 505 | $a1 L. Silva et al., Simulation of Complex High Reynolds Flows with a VMS method and Adaptive Meshing -- 2 B. Bastl et al., Comparison of coupled and decoupled solvers for incompressible Navier-Stokes equations solved by isogeometric analysis -- 3 A. Jaeschke and M. Möller, High-Order Isogeometric Methods for Compressible Flows. I. Scalar Conservation Laws -- 4 M. Möller and A. Jaeschke, High-Order Isogeometric Methods for Compressible Flows. II. Compressible Euler Equations -- 5 G. Tumolo and L. Bonaventura, Simulations of Non-hydrostatic Flows by an Efficient and Accurate p-adaptive DG Method -- 6 L. Bonaventura et al., A fully semi-Lagrangian method for the Navier-Stokes equations in primitive variables -- 7 A. Dervieux et al., Mesh adaptation for k-exact CFD approximations -- 8 M. R. A. Abdelmalik and E. H. van Brummelen, Entropy Stable Discontinuous Galerkin Finite Element Moment Methods for Compressible Fluid Dynamics -- 9 M. Make et al., Space-Time NURBS-Enhanced Finite Elements for Solving the Compressible Navier-Stokes Equations -- 10 S. Santoso et al., Fluid Flow Simulation from geometry data based on point clouds -- 11 C. Miles et al., Thermomechanically-consistent phase-field modelling of thin film flows -- 12 K. Bicol and A. Quaini, On the sensitivity to model parameters in a filter stabilization technique for advection dominated advection-diffusion-reaction problems -- 13 J. K. Ryan and J. Docampo, One-dimensional Line SIAC filtering for multi-dimensions: Applications to Streamline Visualization -- 14 J. H. Spühler et al., A high performance computing framework for finite element simulation of blood flow in the left ventricle of the human heart -- 15 B. S. Hosseini and M. Möller, Phase field-based incompressible two-component liquid flow simulation -- 16 J. Watkins et al., A study on the performance portability of the finite element assembly process within the Albany Land Ice solver -- 17 A. Johansson et al., A MultiMesh Finite Element Method for the Stokes Problem -- 18 Y. Mesri et al., A variational multi-scale anisotropic mesh adaptation scheme for aerothermal problems -- 19 N. Ferro et al., Density-based inverse homogenization with anisotropically adapted elements -- 20 H. Hajduk et al., Bathymetry reconstruction using inverse shallow water -- 21 E. G. Phillips et al., Enabling Scalable Multifluid Plasma Simulations through Block Preconditioning -- 22 S. Hijazi et al., The Effort of Increasing Reynolds Number in Projection-Based Reduced Order Methods: from Laminar to Turbulent Flows -- 23 J. M. Maljaars et al., Optimization Based Particle-Mesh Algorithm for High-Order and Conservative Scalar Transport -- 24 P. T. Lin et al., Krylov smoothing for fully-coupled AMG preconditioners for VMS resistive MHD -- 25 I. K. Marchevsky and G. A. Shcheglov, Double Layer Potential Density Reconstruction Procedure For 3D Vortex Methods -- 26 T. Yamada and K. Goto, Balancing Domain Decomposition Method on Additive Schwartz Framework for Multi-level Implementation -- 27 M. Gerritsma et al., Algebraic dual polynomials for the equivalence of curl-curl problems -- 28 K. Masui et al., Multiple-precision Iterative Methods for Solving Complex Symmetric Electromagnetic Systems -- 29 D. Kuzmin, Gradient-based limiting and stabilization of continuous Galerkin methods -- 30 J. Llobell et al., High order CG schemes for KdV and Saint-Venant flows. |
| 520 | $aThis book includes selected contributions on applied mathematics, numerical analysis, numerical simulation and scientific computing related to fluid mechanics problems, presented at the FEF-"Finite Element for Flows" conference, held in Rome in spring 2017. Written by leading international experts and covering state-of-the-art topics in numerical simulation for flows, it provides fascinating insights into and perspectives on current and future methodological and numerical developments in computational science. As such, the book is a valuable resource for researchers, as well as Masters and Ph.D students. |
| 533 | $aDigital book. Cham Springer Nature 2020. - Mode of access: World Wide Web. System requirements: Internet Explorer 6.0 (or higher) or Firefox 2.0 (or higher). Available as searchable text in PDF format |
| 538 | $a - Online access to this digital book is restricted to subscription institutions through IP address (only for SISSA internal users). |
| 700 | $avan Brummelen, Harald.$eeditor. |
| 700 | $aCorsini, Alessandro.$eeditor. |
| 700 | $aPerotto, Simona.$eeditor. |
| 700 | $aRozza, Gianluigi.$eeditor. |
| 710 | $aSpringerLink (Online service) |
| 830 | $aLecture Notes in Computational Science and Engineering,$v132 |
| 856 | $uhttps://doi.org/10.1007/978-3-030-30705-9 |
