Large-scale transient stability simulation of electrical power systems on parallel GPUs

This paper proposes large-scale transient stability simulation based on the massively parallel architecture of multiple graphics processing units (GPUs). A robust and efficient instantaneous relaxation based parallel processing technique which features implicit integration, full Newton iteration, an...

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Vydáno v:2012 IEEE Power and Energy Society General Meeting s. 1 - 11
Hlavní autoři: Jalili-Marandi, V., Zhiyin Zhou, Dinavahi, V.
Médium: Konferenční příspěvek
Jazyk:angličtina
Vydáno: IEEE 01.07.2012
Témata:
Computational modeling
Graphics processing units
Graphics processors
instantaneous relaxation
large-scale systems
Mathematical model
multiple GPUs
newton-raphson method
parallel multi-threaded programming
power system simulation
Power system stability
power system transient stability
sparse direct solvers
Stability analysis
Transient analysis
ISBN:1467327271, 9781467327275
ISSN:1932-5517
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Shrnutí:This paper proposes large-scale transient stability simulation based on the massively parallel architecture of multiple graphics processing units (GPUs). A robust and efficient instantaneous relaxation based parallel processing technique which features implicit integration, full Newton iteration, and sparse LU based linear solver is used to run the multiple GPUs simultaneously. This implementation highlights the combination of coarse-grained algorithm-level parallelism with fine-grained data-parallelism of the GPUs to accelerate large-scale transient stability simulation. Multi-threaded parallel programming makes the entire implementation highly transparent, scalable and efficient. Several large test systems are used for the simulation with a maximum size of 9984 buses and 2560 synchronous generators all modeled in detail resulting in matrices that are larger than 20000×20000.
ISBN:1467327271
9781467327275
ISSN:1932-5517
DOI:10.1109/PESGM.2012.6343968