Grid computing is an emerging technology for providing the high performance computing capability and collaboration mechanism for solving the collaborated and complex problems while using the existing resources. In this paper, a grid computing based framework is proposed for the probabilistic based power system reliability and security analysis. The suggested name of this computing grid is Reliability and Security Grid (RSA-Grid). Then the architecture of this grid is presented. A prototype system has been built for further development of grid-based services for power systems reliability and security assessment based on probabilistic techniques, which require high performance computing and large amount of memory. Preliminary results based on prototype of this grid show that RSA-Grid can provide the comprehensive assessment results for real power systems efficiently and economically.Index Terms-Grid Computing, Power system reliability and security analysis, probabilistic reliability analysis, Monte Carlo simulation
Ultra-large-scale simulations via solving partial differential equations (PDEs) require very large computational systems for their timely solution. Studies shown the rate of failure grows with the system size, and these trends are likely to worsen in future machines. Thus, as systems, and the problems solved on them, continue to grow, the ability to survive failures is becoming a critical aspect of algorithm development. The sparse grid combination technique (SGCT) which is a cost-effective method for solving higher dimensional PDEs can be easily modified to provide algorithm-based fault tolerance. In this article, we describe how the SGCT can produce fault-tolerant versions of the Gyrokinetic Electromagnetic Numerical Experiment plasma application, Taxila Lattice Boltzmann Method application, and Solid Fuel Ignition application. We use an alternate component grid combination formula by adding some redundancy on the SGCT to recover data from lost processes. User-level failure mitigation (ULFM) message passing interface (MPI) is used to recover the processes, and our implementation is robust over multiple failures and recovery (processes and nodes). An acceptable degree of modification of the applications is required. Results using the 2-D SGCT show competitive execution times with acceptable error (within 0.1% to 1.0%), compared to the same simulation with a single full resolution grid. The benefits improve when the 3-D SGCT is used. Experiments show the applications ability to successfully recover from multiple failures, and applying multiple SGCT reduces the computed solution error. Process recovery via ULFM MPI increases from approximately 1.5 sec at 64 cores to approximately 5 sec at 2048 cores for a one-off failure. This compares applications' built-in checkpointing with job restart in conjunction with the classical SGCT on failure, which have overheads four times as large for a single failure, excluding the recomputation overhead. An analysis for a long-running application considering recomputation times indicates a reduction in overhead of over an order of magnitude.
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