In: Tatra Mountains Mathematical Publications, vol. 75, no. 1
Marek Macák - Zuzana Minarechová - Róbert Čunderlík - Karol Mikula
Details:
Year, pages: 2020, 63 - 80
Language: eng
Keywords:
oblique derivative boundary value problem, finite element method.
Article type: Applied Mathematics
Document type: Scientific paper
About article:
In this paper, we propose a novel approach to approximate the solution of the Laplace equation with an oblique derivative boundary condition by the finite element method. We present and analyse diverse testing experiments to study its behaviour and convergence. Finally, the usefulness of this approach is demonstrated by using it to gravity field modelling, namely, to approximate the solution of a geodetic boundary value problem in Himalayas.
How to cite:
ISO 690:
Macák, M., Minarechová, Z., Čunderlík, R., Mikula, K. 2020. The finite element method as a tool to solve the oblique derivative boundary value problem in geodesy: Applied Mathematics ´19. In Tatra Mountains Mathematical Publications, vol. 75, no.1, pp. 63-80. 1210-3195. DOI: https://doi.org/10.2478/tmmp-2020-0005
APA:
Macák, M., Minarechová, Z., Čunderlík, R., Mikula, K. (2020). The finite element method as a tool to solve the oblique derivative boundary value problem in geodesy: Applied Mathematics ´19. Tatra Mountains Mathematical Publications, 75(1), 63-80. 1210-3195. DOI: https://doi.org/10.2478/tmmp-2020-0005
About edition:
Publisher: Mathematical Institute, Slovak Academy of Sciences, Bratislava
Published: 2. 4. 2020
Rights:
Licensed under the Creative Commons Attribution-NC-ND4.0 International Public License.