Your search keyword '"Giorgio Micaletto"' showing total 2 results

1. Parallel implementation of the SHYFEM (System of HydrodYnamic Finite Element Modules) model

Author

Giorgio Micaletto, Ivano Barletta, Silvia Mocavero, Ivan Federico, Italo Epicoco, Giorgia Verri, Giovanni Coppini, Pasquale Schiano, Giovanni Aloisio, Nadia Pinardi, Micaletto, G., Barletta, I., Mocavero, S., Federico, I., Epicoco, I., Verri, G., Coppini, G., Schiano, P., Aloisio, G., and Pinardi, N.

Subjects

General Medicine

Abstract

This paper presents the message passing interface (MPI)-based parallelization of the three-dimensional hydrodynamic model SHYFEM (System of HydrodYnamic Finite Element Modules). The original sequential version of the code was parallelized in order to reduce the execution time of high-resolution configurations using state-of-the-art high-performance computing (HPC) systems. A distributed memory approach was used, based on the MPI. Optimized numerical libraries were used to partition the unstructured grid (with a focus on load balancing) and to solve the sparse linear system of equations in parallel in the case of semi-to-fully implicit time stepping. The parallel implementation of the model was validated by comparing the outputs with those obtained from the sequential version. The performance assessment demonstrates a good level of scalability with a realistic configuration used as benchmark.

Published

2022

2. Parallel Implementation of the SHYFEM Model

Author

Italo Epicoco, Giorgia Verri, Giorgio Micaletto, Ivan Federico, Pasquale Schiano, Nadia Pinardi, Silvia Mocavero, Giovanni Aloisio, Ivano Barletta, and Giovanni Coppini

Subjects

Computer science, Scalability, Message Passing Interface, Benchmark (computing), Distributed memory, Parallel computing, Load balancing (computing), Partition (database), Finite element method, Unstructured grid

Abstract

This paper presents the MPI-based parallelization of the three-dimensional hydrodynamic model SHYFEM (System of HydrodYnamic Finite Element Modules). The original sequential version of the code was parallelized in order to reduce the execution time of high-resolution configurations using state-of-the-art HPC systems. A distributed memory approach was used, based on the message passing interface (MPI). Optimized numerical libraries were used to partition the unstructured grid (with a focus on load balancing) and to solve the sparse linear system of equations in parallel in the case of semi-to-fully implicit time stepping. The parallel implementation of the model was validated by comparing the outputs with those obtained from the sequential version. The performance assessment demonstrates a good level of scalability with a realistic configuration used as benchmark.

Published

2021