A PAPER SURVEY ON THE IMPLEMENTATION OF THE PARALLEL FDTD ON MULTIPROCESSORS USING MPI

Adamu Abubakar Isah; Oyku Akaydin; Mehmet Kusaf

doi:10.25212/lfu.qzj.2.2.07

Authors

Adamu Abubakar Isah Computer Engineering, Cyprus International University – North Cyprus
Oyku Akaydin Computer Engr and Elect Elect Department, Cyprus International University – North Cyprus
Mehmet Kusaf Computer Engr and Elect Elect Department, Cyprus International University – North Cypru

DOI:

https://doi.org/10.25212/lfu.qzj.2.2.07

Keywords:

Distributed, shared, memory, computer architectures and parallel computing.

Abstract

The research work explains a cost-effective, highperformance computing platform for the parallel implementation of the FDTD algorithm on PC clusters using the message-passing interface (MPI) library, which is a local area network system consisting of multiple interconnected personal computers (PCs), and is already widely employed for parallel computing.

Downloads

Download data is not yet available.

References

O. Ramadan, O. Akaydin, M. Salamah, and A.Y.Oztoprak, ”Parallel Implementation of the Wave-Equation Finite-Difference Time-Domain Method Using the Message Passing Interface,” Lecture Notes on Computer Science (LNCS), Vol. 3280, 2004, pp. 810-818

K.S. Yee, ”Numerical solution of initial boundary value problems involving Maxwell’s equations in isotropic media,” IEEE Transaction on Antennas and Propagation, Vol. 14, 1966, pp. 302–307

Mehmet Kusaf and Abdullah Y. Oztoprak : Multi split-step unconditionally stable finite difference time domain methods August 2009

I. R. Capoglu, A. Taflove, V. Backman, "A Frequency-Domain Near-Field-to-Far-Field Transform for Planar Layered Media", IEEE Transactions on Antennas and Propagation, vol. AP-60, no. 4, pp. 1878-1885, April 2012.

M. Avinash Reddy, et al., “Gain and Bandwidth Enhancement of a MSP Antenna Over Multiple-layer Dielectric Substrate”, International Journal of Advances in Computer, Vol. 3, pp. 55-57, March 2014.

W. Yu, X. Yang , Y. Liu , R. Mittra, and A. Muto, Advanced FDTD Method: Acceleration, Parallelization and Engineering Applications, Artech House, Norwood, Mass, USA, 2011.

K. Yee, “Numerical solution of initial boundary value problems involving Maxwell’s equations in isotropic media,” IEEE Transactions on Antennas and Propagation, vol. 14, no. 5, pp. 302–307, 1966.

A. Taflove and S. Hagness, Computational Electrodynamics the Finite-Difference Time Domain Method, Artech House, Norwood, Mass, USA, 2005

L. Catarinucci, S. Guglielmi, R. Colella, L. Tarricone,“Compact switched-beam antennas enabling novel power-efficient wireless sensor networks”IEEE Sensors Journal, 14 (9), pp. 3252-3259, 2014

Fenghua,Z. & Zhizhang, C. (2001). Numerical Dispersion Analysis of the Unconditionally Stable 3-D ADI-FDTD Method: IEEE Transactions on microwave theory and technique, vol.49, no.5.

F.D. Hastings and others, "application of the perfectly matched layer (pml) absorbing boundary-condition to elastic-wave propagation", The Journal of the Acoustical Society of America, 100(5), 1996, pp. 3061-3069

Fu, W., & Tan, E. (2004). Development of split-step FDTD method with higher-order spatial accuracy: IEEE Electronics letter, vol.40, no.20.

F.Zhang, Z Chen and J. Zhang”Towards the development of a three dimensional unconditionally stable finite difference time domain method”, IEEE Trans. microwave theory Tech, Vol 48, no 9, 2000.

Guilin, S. (2004). Development & Evaluation of Novel Finite-Difference Time-Domain methods for solving Maxwell’s equations (PhD dissertation) Canada, Concordia University, Montreal, Quebec, Canada.

1 Harari, E. Turkel Accurate finite difference methods for time-harmonic wave propagation J. Comput. Phys., 119 (1995), pp. 252–270.

Jaakko, S. & Theodoros, D. (2000). Reduction of Numerical Dispersion in FDTD method through artificial Anisotropy: IEEE Transactions on microwave Theory and Techniques, vol.48, no.4, April 2000.