Agros2D

Agros2D
Developer(s) University of West Bohemia
Stable release 3.2 / March 3, 2014 (2014-03-03)
Operating system Linux, Windows
Available in C++, Python
Type Scientific simulation software
License GNU General Public License
Website http://www.agros2d.org

Agros2D is an open-source code for numerical solutions of 2D coupled problems in technical disciplines. Its principal part is a user interface serving for complete preprocessing and postprocessing of the tasks (it contains sophisticated tools for building geometrical models and input of data, generators of meshes, tables of weak forms for the partial differential equations and tools for evaluating results and drawing graphs and maps). The processor is based on the library Hermes containing the most advanced numerical algorithms for monolithic and fully adaptive solution of systems of generally nonlinear and nonstationary partial differential equations (PDEs) based on hp-FEM (adaptive finite element method of higher order of accuracy). Both parts of the code are written in C++.[1]

Features

Highlights of capabilities

Physical Fields

Couplings

History

The software started from work at the hp-FEM Group at University of West Bohemia in 2009. The first public version was released at the beginning of year 2010. Agros2D has been used in many publications.[2][3][4][5][6][7][8]

See also

References

  1. Karban, P., Mach, F., Kůs, P., Pánek, D., Doležel, I.: Numerical solution of coupled problems using code Agros2D, Computing, 2013, Volume 95, Issue 1 Supplement, pp 381-408
  2. Dolezel, I., Karban, P., Mach, F., & Ulrych, B. (2011, July). Advanced adaptive algorithms in finite element method of higher order of accuracy. In Nonlinear Dynamics and Synchronization (INDS) & 16th Int'l Symposium on Theoretical Electrical Engineering (ISTET), 2011 Joint 3rd Int'l Workshop on (pp. 1-4). IEEE.
  3. Polcar, P. (2012, May). Magnetorheological brake design and experimental verification. In ELEKTRO, 2012 (pp. 448-451). IEEE.
  4. Lev, J., Mayer, P., Prosek, V., & Wohlmuthova, M. (2012). The Mathematical Model of Experimental Sensor for Detecting of Plant Material Distribution on the Conveyor. Main Thematic Areas, 97.
  5. Kotlan, V., Voracek, L., & Ulrych, B. (2013). Experimental calibration of numerical model of thermoelastic actuator. Computing, 95(1), 459-472.
  6. Vlach, F., & Jelínek, P. (2014). Determination of linear thermal transmittance for curved detail. Advanced Materials Research, 899, 112-115.
  7. Kyncl, J., Doubek, J., & Musálek, L. (2014). Modeling of Dielectric Heating within Lyophilization Process. Mathematical Problems in Engineering, 2014.
  8. De, P. R., Mukhopadhyay, S., & Layek, G. C. (2012). Analysis of fluid flow and heat transfer over a symmetric porous wedge. Acta Technica CSAV, 57(3), 227-237.

External links

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