GENETATOMICS
From HP-SEE Wiki
Contents |
General Information
- Application's name: Genetic algorithms in atomic collisions
- Virtual Research Community: Computational Physics
- Scientific contact: Dragan Jakimovski, dragan.jakimovski@gmail.com
- Technical contact: Jane Jovanovski, janejovanovski@gmail.com
- Developers: Faculty of Natural Science and Mathematics, UKIM, FYROMacedonia
- Web site:
Short Description
'The computer simulation and modeling of various processes involving highly charged ions in plasma are extremely important in contemporary physics. The knowledge of cross sections of electron capture and ionization processes as well as of corresponding sections for excitation of electron(s) in atoms and ions colliding with impurity ions in reactor plasma is valuable in calculations of other plasma parameters and diagnostics of its characteristics in experimental reactor ITER to be build in France. Of special interest are the details of cross sections for different plasma temperatures. The usage of HPC for this application will increase the performance of the genetic algorithms, allowing processing of more parameters and larger intervals in single run.
Problems Solved
The objective of our work is to calculate these multivariable functions (which arise with Schrodinger equation in general) with different values of parameters and different ranges of variables, which in many cases is computer intensive, and require high amount of CPU time. For now the code has been tested, also on various other systems of equations, prominent in physics, applied mathematics and economics
- Volter-Lotka system,
- Equations with non-analytical solutions, and
- GDP equations from economic theory
For systems for which there is known analytical solution the comparison with the numerically obtained result is excellent.
Scientific and Social Impact
Contribution to IAEA and atomic collisions research community, as well as research groups in quantum physics in general. The availability of robust, thoroughly tested parallel genetic algorithm code for various quantum problems with different effective potentials should be beneficial to all those developers interested in independent check of their own, more specialised codes. Possible scaling of the code to large number of processors (up to, say 100) for solving more complex problems and eventually to huge number of more than 100 thousand, processors with different hardware / software environment may prove itself to have important social impact.
Collaborations
International Atomic Energy Agency, Vienna
Beneficiaries
- Research groups working in atomic / ion collisions and quantum physics in general, for double-checking their own codes;
- Universities and educational centres with strong program in HP physics computing
Technical Features and HP-SEE Implementation
- Primary programming language: FORTRAN
- Parallel programming paradigm: SMP and MPI
- Main parallel code: In-house development
- Pre/post processing code: In-house development
Resource requirements
- Application tools and libraries: none
- Number of cores required: 128 - 2048
- Minimum RAM/core required: 0.5GB
- Storage space during a single run: 10MB
- Long-term data storage: 5GB
Usage Example
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Publications
- J Jovanovski, B Jakimovski and D Jakimovski, Parallel Genetic Algorithms for Finding Solution of System of Ordinary Differential Equations, publication submitted to ICT Innovations 2011 conference
