SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W621523575> ?p ?o ?g. }

Showing items 1 to 100 of ±158 with 100 items per page.

W621523575 abstract "This PhD thesis proposes a p-adaptive technique for the Hybridizable Discontinuous Galerkin method (HDG). The HDG method is a novel discontinuous Galerkin method (DG) with interesting characteristics. While retaining all the advantages of the common DG methods, such as the inherent stabilization and the local conservation properties, HDG allows to reduce the coupled degrees of freedom of the problem to those of an approximation of the solution de¿ned only on the faces of the mesh. Moreover, the convergence properties of the HDG solution allow to perform an element-by-element postprocess resulting in a superconvergent solution.  Due to the discontinuous character of the approximation in HDG, p-variable computations are easily implemented. In this work the superconvergent postprocess is used to de¿ne a reliable and computationally cheap error estimator, that is used to drive an automatic adaptive process. The polynomial degree in each element is automatically adjusted aiming at obtaining a uniform error distribution below a user de¿ned tolerance. Since no topological modi¿cation of the discretization is involved, fast adaptations of the mesh are obtained.  First, the p-adaptive HDG is applied to the solution of wave problems. In particular, the Mild Slope equation is used to model the problem of sea wave propagation is coastal areas and harbors. The HDG method is compared with the continuous Galerkin (CG) ¿nite element method, which is nowadays the common method used in the engineering practice for this kind of applications. Numerical experiments reveal that the e¿ciency of HDG is close to CG for uniform degree computations, clearly outperforming other DG methods such as the Compact Discontinuous Galerkin method. When p-adaptivity is considered, an important saving in computational cost is shown.  Then, the methodology is applied to the solution of the incompressible Navier-Stokes equations for the simulation of laminar ¿ows. Both steady state and transient applications are considered. Various numerical experiments are presented, in 2D and 3D, including academic examples and more challenging applications of engineering interest. Despite the simplicity and low cost of the error estimator, high e¿ciency is exhibited for analytical examples. Moreover, even though the adaptive technique is based on an error estimate for just the velocity ¿eld, high accuracy is attained for all variables, with sharp resolution of the key features of the ¿ow and accurate evaluation of the ¿uid-dynamic forces. In particular, high degrees are automatically located along boundary layers, reducing the need for highly distorted elements in the computational mesh. Numerical tests show an important reduction in computational cost, compared to uniform degree computations, for both steady and unsteady computations." @default.
W621523575 created "2016-06-24" @default.
W621523575 creator A5034433194 @default.
W621523575 date "2023-10-13" @default.
W621523575 modified "2023-10-14" @default.
W621523575 title "Adaptive hybrid discontinuous methods for fluid and wave problems" @default.
W621523575 cites W1564626571 @default.
W621523575 cites W1573653535 @default.
W621523575 cites W1573761753 @default.
W621523575 cites W173645500 @default.
W621523575 cites W1965314915 @default.
W621523575 cites W1966525999 @default.
W621523575 cites W1967757175 @default.
W621523575 cites W1970351891 @default.
W621523575 cites W1971016819 @default.
W621523575 cites W1974983713 @default.
W621523575 cites W1977110629 @default.
W621523575 cites W1977111034 @default.
W621523575 cites W1978682560 @default.
W621523575 cites W1986468439 @default.
W621523575 cites W1988754720 @default.
W621523575 cites W1990980450 @default.
W621523575 cites W1992833209 @default.
W621523575 cites W1998050976 @default.
W621523575 cites W1998739679 @default.
W621523575 cites W1998894128 @default.
W621523575 cites W2003017040 @default.
W621523575 cites W2007203297 @default.
W621523575 cites W2008021403 @default.
W621523575 cites W2008242326 @default.
W621523575 cites W2008325195 @default.
W621523575 cites W2008711303 @default.
W621523575 cites W2011572706 @default.
W621523575 cites W2012938047 @default.
W621523575 cites W2012965796 @default.
W621523575 cites W2017488448 @default.
W621523575 cites W2029342920 @default.
W621523575 cites W2030341996 @default.
W621523575 cites W2036956780 @default.
W621523575 cites W2037092148 @default.
W621523575 cites W2037471917 @default.
W621523575 cites W2041458840 @default.
W621523575 cites W2042202893 @default.
W621523575 cites W2048282888 @default.
W621523575 cites W2048929651 @default.
W621523575 cites W2059624850 @default.
W621523575 cites W2059953548 @default.
W621523575 cites W2062509375 @default.
W621523575 cites W2063654460 @default.
W621523575 cites W2069036386 @default.
W621523575 cites W2071831755 @default.
W621523575 cites W2071897054 @default.
W621523575 cites W2073370219 @default.
W621523575 cites W2073662629 @default.
W621523575 cites W2076077791 @default.
W621523575 cites W2079263908 @default.
W621523575 cites W2082452417 @default.
W621523575 cites W2089683928 @default.
W621523575 cites W2091354775 @default.
W621523575 cites W2091907831 @default.
W621523575 cites W2092011174 @default.
W621523575 cites W2096441753 @default.
W621523575 cites W2096969540 @default.
W621523575 cites W2100903519 @default.
W621523575 cites W2104426156 @default.
W621523575 cites W2104882039 @default.
W621523575 cites W2115909803 @default.
W621523575 cites W2117443301 @default.
W621523575 cites W2118922968 @default.
W621523575 cites W2120239346 @default.
W621523575 cites W2120874885 @default.
W621523575 cites W2129639910 @default.
W621523575 cites W2133162771 @default.
W621523575 cites W2137332760 @default.
W621523575 cites W2141278134 @default.
W621523575 cites W2147584861 @default.
W621523575 cites W2149374694 @default.
W621523575 cites W2153879580 @default.
W621523575 cites W2155395549 @default.
W621523575 cites W2161433750 @default.
W621523575 cites W2161695731 @default.
W621523575 cites W2182245590 @default.
W621523575 cites W2491027544 @default.
W621523575 cites W3022909171 @default.
W621523575 cites W3023870838 @default.
W621523575 cites W49087508 @default.
W621523575 cites W618086462 @default.
W621523575 doi "https://doi.org/10.5821/dissertation-2117-94916" @default.
W621523575 hasPublicationYear "2023" @default.
W621523575 type Work @default.
W621523575 sameAs 621523575 @default.
W621523575 citedByCount "0" @default.
W621523575 crossrefType "dissertation" @default.
W621523575 hasAuthorship W621523575A5034433194 @default.
W621523575 hasBestOaLocation W6215235751 @default.
W621523575 hasConcept C105795698 @default.
W621523575 hasConcept C11413529 @default.
W621523575 hasConcept C121332964 @default.
W621523575 hasConcept C126255220 @default.
W621523575 hasConcept C127413603 @default.