SINUMCC. Ponencias / Actashttp://hdl.handle.net/10366/1381612026-04-20T07:39:35Z2026-04-20T07:39:35ZSolar Radiation Modelling and ForecastingDíaz Reyes, FelipeMontero, GustavoMontenegro Armas, RafaelMazorra Aguiar, LuisRodríguez, EduardoEscobar, José Maríahttp://hdl.handle.net/10366/1382132025-04-30T20:46:19Z2018-06-01T00:00:00Z[EN]In this paper, an adaptive solar radiation numerical model for complex terrains is described.
2018-06-01T00:00:00ZA High Resolution DiagnosticWind Model. Application to Downscaling Mesoscale Model Results for Wind ForecastingMontero, GustavoMontenegro Armas, RafaelEscobar, José MaríaRodríguez, EduardoOliver, AlbertSuárez, A.http://hdl.handle.net/10366/1382122025-04-30T20:46:19Z2018-06-01T00:00:00Z[EN]A mass consistent wind model is improved by introducing three items: the new 3-D mesh generator MECCANO applied to complex terrains, the current atmospheric stability definition by Zilitinkevich including new wind profiles, and a specific preconditioner for the linear systems arising in a wind model.
2018-06-01T00:00:00ZAnalysis of several objective functions for optimization of hexahedral meshesLópez González, José IvánBrovka, MarinaEscobar, José MaríaMontenegro Armas, RafaelSocorro-Marrero, Guillermo Valentínhttp://hdl.handle.net/10366/1382072025-04-30T20:46:19Z2016-06-01T00:00:00Z2016-06-01T00:00:00ZWind Ensemble Forecasting Using Differential EvolutionRodríguez, EduardoMontero, GustavoOliver, AlbertSocorro-Marrero, Guillermo ValentínMontenegro Armas, Rafaelhttp://hdl.handle.net/10366/1382062025-04-30T20:46:19Z2016-06-01T00:00:00Z[en]In this work we propose to apply ensemble methods to a local scale adaptive wind forecasting model.
2016-06-01T00:00:00ZA Methodology to Map Roughness Length and Displacement Height in Complex TerrainMontero, GustavoRodríguez, EduardoOliver, AlbertSocorro-Marrero, Guillermo Valentínhttp://hdl.handle.net/10366/1382052025-04-30T20:46:18Z2016-06-01T00:00:00Z2016-06-01T00:00:00ZGeneración de Mallas y Simulación Numérica en MedioambienteMontenegro Armas, RafaelMontero, GustavoEscobar, José MaríaRodríguez, EduardoDíaz Reyes, FelipeCascón Barbero, José ManuelOliver, AlbertMazorra Aguiar, LuisBrovka, MarinaLópez González, José IvánRamírez, J.Ramos, A.Socorro-Marrero, Guillermo Valentínhttp://hdl.handle.net/10366/1382042025-04-30T20:46:18Z2017-02-01T00:00:00Z[ES]En esta conferencia se introducen ideas básicas sobre la simulación numérica, mediante el método de los elementos finitos (MEF), de problemas medioambientales que han sido abordados por nuestro grupo en diversos proyectos de investigación sobre simulación de campos de viento, radiación solar, contaminación atmosférica y la modelización de yacimientos de petróleo.
2017-02-01T00:00:00ZConstruction of polynomial spline spaces over quadtree and octree T-meshes for its application in isogeometric analysisLópez González, José IvánBrovka, MarinaEscobar, José MaríaMontenegro Armas, Rafaelhttp://hdl.handle.net/10366/1382032025-04-30T20:46:18Z2017-04-01T00:00:00Z[EN]We present a new strategy for construction spline spaces over hierarchical T-meshes with quad- and
octree subdivision scheme.
2017-04-01T00:00:00ZThe Meccano Method for Mesh Generation and Solid ParameterizationMontenegro Armas, RafaelCascón Barbero, José ManuelEscobar, José MaríaRodríguez, EduardoOliver, AlbertMontero, GustavoBrovka, MarinaLópez González, José IvánBenítez, Domingohttp://hdl.handle.net/10366/1381822025-04-30T20:46:18Z2018-06-01T00:00:00Z[EN]In this conference, we present the main advances in the meccano method, which was introduced by the authors in 2006 for tetrahedral mesh generation.
2018-06-01T00:00:00ZNumerical methods for free boundary problemsFerragut Canals, Luishttp://hdl.handle.net/10366/1381812023-06-13T04:02:58Z2018-06-01T00:00:00Z[EN]This lecture is a survey concerning different numerical methods to solve free boundary problems, mainly focussing in:
Solving variational inequalities
Adaptive Finite Element methods
Level set methods
2018-06-01T00:00:00ZNeptuno ++: An Adaptive Finite Element Toolbox for Numerical Simulation of Environmental ProblemsCascón Barbero, José ManuelFerragut Canals, LuisAsensio Sevilla, María IsabelPrieto Herráez, DiegoÁlvarez León, Davidhttp://hdl.handle.net/10366/1381802025-04-30T20:46:18Z2018-06-01T00:00:00Z[EN]In this talk, we show some of the main features of Neptuno++, through several examples. Neptuno++ is a finite element toolbox mainly developed by L. Ferragut at SINUMCC (Group of Numerical Simulation and
Scientific Computation) and implemented in C++.
2018-06-01T00:00:00ZPhyFire & HDWind: from the initial ideas to the current toolAsensio Sevilla, María IsabelFerragut Canals, LuisPrieto Herráez, DiegoÁlvarez León, DavidCascón Barbero, José Manuelhttp://hdl.handle.net/10366/1381792025-04-30T20:46:17Z2018-06-01T00:00:00Z[EN]We present a historical review of PhyFire and HDWind, both
models developed by the research group on Numerical Simula-
tion and Scientific Computation founded by L. Ferragut at the
University of Salamanca.
2018-06-01T00:00:00ZUrban Air Quality Modelling using Finite ElementsOliver, AlbertRodríguez, EduardoMontero, GustavoMontenegro Armas, Rafaelhttp://hdl.handle.net/10366/1381762025-04-30T20:46:17Z2018-06-01T00:00:00Z[EN]Urban air quality simulation requires models with di erent characteristics to those used in mesoscale or microscale. The spatial discretisation resolution is one of them. Urban geometries require smaller elements than those in other scales. Mesh for this kind of geometries are generated using the Meccano method; a mesh generator that has generated high-quality meshes of complex geometries [1]. In this work, we have added capabilities to insert buildings into the mesh maintaining the element quality. Wind eld should also
be suitable for urban scale. To this end, we will use a mass-consistent model [2]. Thisapproximation has performed e ciently in microscale problems, coupling with mesoscale numerical weather prediction models. Finally, an adaptive nite element method is used to simulate the convection-di usion-reaction equation [3, 4]. The problem can be convectiondominant, so it is stabilised using a Least-Squares nite element method. The resulting matrix is symmetric and is solved using the Conjugate Gradient method preconditioned with an incomplete Cholesky factorisation. The model is applied to the city of Las Palmas de Gran Canaria.
2018-06-01T00:00:00ZParallel optimization of tetrahedral meshesBenítez, DomingoRodríguez, EduardoEscobar, José MaríaMontenegro Armas, Rafaelhttp://hdl.handle.net/10366/1381752025-04-30T20:46:17Z2018-06-01T00:00:00Z[EN]We propose a new algorithm on distributed-memory parallel computers for our simultaneous untangling and smoothing of tetrahedral meshes [9, 10]. A previous parallel implementation on shared-memory computers is analyzed in [1]. The new parallel procedure takes ideas from Freitag et al. strategy [11]. The method is based on: partitioning a mesh, optimizing interior vertices, optimizing boundary vertices of interior partitions, and communicating updated coordinates of boundary vertices. This paper presents performance evaluation results of our parallel algorithm. We apply the procedure in the mesh generation of several 3-D objects by using the Meccano method [4]. High levels of speed-up are obtained in the mesh optimization step of this method. How
ever, several bottlenecks may limit the parallelism. We provide some hypotheses about the factors that cause more parallel overhead. The relative number of elements, that are located at the interfaces of the sub-domains of the object, is one of the more important aspects for the e ciency of the parallel mesh optimization.
2018-06-01T00:00:00ZA downscale wind forecasting method based on WRF-HDMW couplingAsensio Sevilla, María IsabelCascón Barbero, José ManuelFerragut Canals, LuisHernández, Erwinhttp://hdl.handle.net/10366/1381742025-04-30T20:46:17Z2017-07-01T00:00:00Z[EN]In this paper, we propose a wind prediction strategy based on a mesoscale-microscale coupling
technique. We will use the Weather Research and Forecast (WRF) [3] prediction as input data
for the High Wind Defintion Model (HWDM) [2] to yield the forecast on a wind farm.
2017-07-01T00:00:00ZApproximation of Immersed Surfaces Into a Tetrahedral Mesh Generated by the Meccano MethodSocorro-Marrero, Guillermo ValentínOliver, AlbertRuiz-Gironés, EloiCascón Barbero, José ManuelRodríguez, EduardoEscobar, José MaríaMontenegro Armas, RafaelSarrate, Josephttp://hdl.handle.net/10366/1381732025-04-30T20:46:17Z2017-06-01T00:00:00Z[EN]In this paper, we present a new method to insert open surfaces into an existing tetrahedral mesh generated by the meccano method. The surfaces must be totally immersed in the mesh and must not intersect between them. The strategy includes a mesh refinement to obtain an initial approximation of each surface capturing its geometric features, the projection of the nodes from the approximation onto the actual surface, and the mesh optimization. The proposed method provides a high-quality conformal mesh with interpolations of the inserted surfaces. These approximations are suitable for operations where roughness is a major problem and a smoother solution is required, such as the estimation of normal vectors or the imposition of Neumann
conditions.
2017-06-01T00:00:00ZWind field simulation with isogeometric analysisMontenegro Armas, RafaelEscobar, José MaríaLópez González, José IvánBrovka, MarinaOliver, AlbertMontero, Gustavohttp://hdl.handle.net/10366/1381722025-04-30T20:46:17Z2017-06-01T00:00:00Z[EN]For wind field simulation with isogeometric analysis, firstly it is necessary to generate a spline parameterization of the computational domain, which is an air layer above the terrain surface. This parameterization is created with the meccano method from a digital terrain model. The main steps of the meccano method for tetrahedral mesh generation were introduced in [1, 2]. Based on the volume parameterization obtained by the method, we can generate a mapping from the parametric T-mesh to the physical space [3, 4]. Then, this volumetric parameterization is used to generate a cubic spline representation of the physical domain for the application of isogeometric analysis. We consider a mass-consistent model [5] to compute the wind field simulation in
the three-dimensional domain from wind measurements or a wind forecasted by a meteorological model (for example, WRF or HARMONIE). From these data, an interpolated wind field is constructed. The mass-consistent model obtains a new wind field approaching the interpolated one, but verifying the continuity equation (mass conservation) for constant density and the impermeabilitycondition on the terrain. This adjusting problem is solved by introducing a Lagrange multiplier, that is the solution of a Poisson problem. The resulting field is obtained from the interpolated one and the gradient of the Lagrange multiplier. It is well known that if we use classical Lagrange finite elements, the gradient of the numerical solution is discontinuous over the element boundary. The advantage of using isogeometric analysis with cubic polynomial basis functions [6, 7] is that we obtain a C2 continuity for the Lagrange multiplier in the whole domain. In consequence, the resulting wind field is better approximated. Applications of the proposed technique are presented.
2017-06-01T00:00:00Z