GiD

GiD is a universal, adaptive and user-friendly pre and postprocessor for numerical simulations in science and engineering. It has been designed to cover all the common needs in the numerical simulations field from pre to post-processing: geometrical modeling, effective definition of analysis data, meshing, data transfer to analysis software, as well as the visualization of numerical results. Universal: GiD is ideal for generating all the information required for the analysis of any problem in science and engineering using numerical methods: structured, unstructured or particle based meshes, boundary and loading conditions, material types, visualization of numerical results, etc. Adaptive: GiD is extremely easy to adapt to any numerical simulation code. In fact, GiD can be defined by the user to read and write data in an unlimited number of formats. GiD’s input and output formats can be customised and made compatible with an existing in-house software. The different menus can be tailored to the specific needs and desires of the user. User-friendly: the development of GiD has been focused on the needs of the user and on the simplicity, speed, effectiveness and accuracy the user demands at input data preparation and results visualization levels.


References in zbMATH (referenced in 55 articles )

Showing results 21 to 40 of 55.
Sorted by year (citations)
  1. Zouain, Nestor; Borges, Lavinia; Silveira, José Luís: Quadratic velocity-linear stress interpolations in limit analysis (2014)
  2. Barros, Felício B.; de Barcellos, Clovis S.; Duarte, C. Armando; Torres, Diego A. F.: Subdomain-based error techniques for generalized finite element approximations of problems with singular stress fields (2013)
  3. Kamran, K.; Rossi, R.; Oñate, E.: A contact algorithm for shell problems via Delaunay-based meshing of the contact domain (2013)
  4. Kamran, K.; Rossi, R.; Oñate, E.; Idelsohn, S. R.: A compressible Lagrangian framework for the simulation of the underwater implosion of large air bubbles (2013)
  5. Kirkup, S. M.; Thompson, A.; Kolbrek, Bjørn; Yazdani, J.: Simulation of the acoustic field of a Horn loudspeaker by the boundary element-Rayleigh integral method (2013)
  6. Otin, Ruben: ERMES: a nodal-based finite element code for electromagnetic simulations in frequency domain (2013)
  7. Cervera, M.; Chiumenti, M.; Di Capua, D.: Benchmarking on bifurcation and localization in (\mathrmJ_2) plasticity for plane stress and plane strain conditions (2012)
  8. Nguyen, Giang D.: A damage model with evolving nonlocal interactions (2011)
  9. Dadvand, Pooyan; Rossi, Riccardo; Oñate, Eugenio: An object-oriented environment for developing finite element codes for multi-disciplinary applications (2010)
  10. Makrodimopoulos, Athanasios; Bhaskar, Atul; Keane, Andy J.: Second-order cone programming formulations for a class of problems in structural optimization (2010)
  11. Nguyen, Giang D.; Einav, Itai: Nonlocal regularisation of a model based on breakage mechanics for granular materials (2010)
  12. Phansri, Bupavech; Park, Kyung-Ho; Warnitchai, Pennung: A BEM formulation for inelastic transient dynamic analysis using domain decomposition and particular integrals (2010)
  13. Cervera, M.; Chiumenti, M.: Size effect and localization in J2 plasticity (2009)
  14. Lam, X. B.; Kim, Y. S.; Hoang, A. D.; Park, C. W.: Coupled aerostructural design optimization using the Kriging model and integrated multiobjective optimization algorithm (2009)
  15. Castelló, Walter B.; Flores, Fernando G.: A triangular finite element with local remeshing for the large strain analysis of axisymmetric solids (2008)
  16. Cervera, M.: An orthotropic mesh-corrected crack model (2008)
  17. Cervera, M.: A smeared-embedded mesh-corrected damage model for tensile cracking (2008)
  18. Owatsiriwong, A.; Park, K. H.: A BEM formulation for transient dynamic elastoplastic analysis via particular integrals (2008)
  19. Peratta, A.: 3D low frequency electromagnetic modelling of the human eye with boundary elements: application to conductive keratoplasty (2008)
  20. Logg, Anders: Automating the finite element method (2007)