Distributed Simulation Applied to Shipboard Power Systems

The development of shipboard power systems for the new generation of all-electric ships is challenging in two aspects. First, all new equipment needs to be tested before being installed onboard; otherwise, the design and testing process would become increasingly costly and risky. Second, the complexity of a shipboard power system demands the use of significant computational resources for detailed computer-aided analysis. Distributed simulation techniques can help reduce the computational load that simulation of shipboard power systems requires by partitioning the system into smaller, more manageable subsystems. Distributed simulation can also facilitate remote testing of equipment and collaboration among research teams located in geographically distant institutions. The initial step in distributed simulation requires achieving software-to-software communication over a network. This paper outlines the progress done at the Mississippi State University in the distributed simulation application to shipboard power systems. Both natural and signal coupling models for distributed simulation are developed and validated. For natural coupling, a general coupling method, which considers transmission lines as suitable decoupling points, is proposed. Distributed simulation tests on several systems, including a shipboard power system, are documented and simulation results demonstrate the feasibility of applying distributed simulation techniques in advanced shipboard modeling and simulation.

[1]  M. ten Bruggencate,et al.  Parallel Implementations of the Power System Transient Stability Problem on Clusters of Workstations , 1995, Proceedings of the IEEE/ACM SC95 Conference.

[2]  R.A. Dougal,et al.  Symbolically aided model development for an induction machine in virtual test bed , 2004, IEEE Transactions on Energy Conversion.

[3]  O. Wasynczuk,et al.  A model-in-the-loop interface to emulate source dynamics in a zonal DC distribution system , 2005, IEEE Transactions on Power Electronics.

[4]  C. Christopoulos,et al.  Numerical simulation of power circuits using transmission-line modelling , 1990 .

[5]  Vladimir B. Dmitriev-Zdorov Generalized coupling as a way to improve the convergence in relaxation-based solvers , 1996, Proceedings EURO-DAC '96. European Design Automation Conference with EURO-VHDL '96 and Exhibition.

[6]  A. Monti,et al.  Methods for partitioning the system and performance evaluation in power-hardware-in-the-loop simulations - Part II , 2005, 31st Annual Conference of IEEE Industrial Electronics Society, 2005. IECON 2005..

[7]  Alberto L. Sangiovanni-Vincentelli,et al.  The Waveform Relaxation Method for Time-Domain Analysis of Large Scale Integrated Circuits , 1982, IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems.

[8]  Jian Wu,et al.  Distributed simulation for power system analysis including shipboard systems , 2007 .

[9]  N. N. Schulz,et al.  Generalized three phase coupling method for i distributed simulation , 2005 .

[10]  M. L. Crow,et al.  The parallel implementation of the waveform relaxation method for the simulation of structure-preserved power systems , 1990, IEEE International Symposium on Circuits and Systems.