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January 2004 (vol. 15 no. 1)
pp. 1

[1] S.J. Aarseth, “Direct Methods for $N{\hbox{-}}{\rm{Body}}$ Simulations,” Multiple Time Scales, J.U. Brackhill and B.I. Cohen, eds., Academic Press, 1985.
[2] V.S. Adve, R. Bagrodia, J.C. Browne, E. Deelman, A. Dube, E.N. Houstis, J.R. Rice, R. Sakellariou, D.J. Sundaram-Stukel, P.J. Teller, and M.K. Vernon, “POEMS: End-to-End Performance Design of Large Parallel Adaptive Computational Systems,” IEEE Trans. Software Eng., vol. 26, p. 1027, 2000.
[3] V.S. Adve and R. Sakellariou, “Application Representations for Multiparadigm Performance Modeling of Large-Scale Parallel Scientific Codes,” Int'l J. High Performance Computing Applications, vol. 14, p. 304, 2000.
[4] K. Aida, A. Takefusa, H. Nakada, S. Matsuoka, S. Sekiguchi, and U. Nagashima, “Performance Evaluation Model for Scheduling in Global Computing Systems,” Int'l J. High Performance Computing Applications, vol. 14, p. 268, 2000.
[5] S. Aoki, R. Burkhalter, T. Kanaya, T. Yoshié, T. Boku, H. Nakamura, and Y. Yamashita, “Performance of Lattice QCD Programs on CP-PACS,” Parallel Computing, vol. 25, p. 1243, 1999.
[6] R. Bagrodia, R. Meyer, M. Takai, Y. Chen, X. Zeng, J. Martin, and H.Y. Ha Yoon Song, “Parsec: A Parallel Simulation Environment for Complex Systems,” Computer, vol. 31, no. 10, p. 77, 1998.
[7] H.E. Bal, R.A.F. Bhoedjang, R.F.H. Hofman, C.J.H. Jacobs, T. Kielmann, J. Maassen, R. van Nieuwpoort, J. Romein, L. Renambot, T. Rühl, R. Veldema, K. Verstoep, A. Baggio, G. Ballintijn, I. Kuz, G. Pierre, M. van Steen, A.S. Tanenbaum, G. Doornbos, D. Germans, H. Spoelder, E.-J. Baerends, S. van Gisbergen, H. Afsarmanesh, G.D. van Albada, A.S.Z. Belloum, D. Dubbeldam, Z.W. Hendrikse, L.O. Hertzberger, A.G. Hoekstra, K.A. Iskra, B.D. Kandhai, D.C. Koelma, F. van der Linden, B.J. Overeinder, P.M.A. Sloot, P.F. Spinnato, D.H.J. Epema, A. van Gemund, P.P. Jonker, A. Radulescu, C. van Reeuwijk, H.J. Sips, P.M.W. Knijnenburg, M. Lew, F. Sluiter, L. Wolters, H. Blom, and A. van der Steen, “The Distributed ASCI Supercomputer Project,” Operating Systems Rev., vol. 34, p. 76, ACM, Special Interest Group on Operating Systems, 2000.
[8] J. Barnes and P. Hut, “A Hierarchical ${\cal{O}}(N \cdot \log N)$ Force-Calculation Algorithm,” Nature, vol. 324, p. 446, 1986.
[9] H. Cheng, L. Greengard, and V. Rokhlin, “A Fast Adaptive Multiple Algorithm in Three Dimensions,” J. Computational Physics, vol. 155, p. 468, 1999.
[10] P. Cremonesi and C. Gennaro, “Integrated Performance Models for SPMD Applications and MIMD Architectures,” IEEE Tran. Parallel and Distributed Systems, vol. 13, p. 745, 2002.
[11] M.D. Dikaiakos, A. Rogers, and K. Steiglitz, “Functional Algorithm Simulation of the Fast Multipole Method: Architectural Implications,” Parallel Processing Letters, vol. 6, p. 55, 1996.
[12] R.F. Freund and H.J. Siegel, “Heterogeneous Processing,” Computer, vol. 26, no. 6, p. 13, 1993.
[13] T. Fukushige and J. Makino, “$N{\hbox{-}}{\rm{Body}}$ Simulation of Galaxy Formation on the GRAPE-4 Special Purpose Computer,” Proc. Supercomputing Conf., 1996.
[14] Y. Funato, P. Hut, S.L.W. McMillan, and J. Makino, “Time-Symmetrized Kustaanheimo-Stiefel Regularization,” Astronomical J., vol. 112, p. 1697, 1996.
[15] A. van Gemund, “Performance Prediction of Parallel Processing Systems: The Pamela Methodology,” Proc. Seventh ACM Int'l Conf. on Supercomputing, 1993.
[16] A. van Gemund, “Symbolic Performance Modeling of Parallel Systems,” IEEE Trans. Parallel and Distributed Systems, vol. 14, p. 154, 2003.
[17] N.J. Gunther, “The Dynamics of Performance Collapse in Large-Scale Networks and Computers,” Int'l J. High Performance Computing Applications, vol. 14, p. 367, 2000.
[18] D.C. Heggie and P. Hut, The Gravitational Million Body Problem. Cambridge Univ. Press, 2003.
[19] R.W. Hockney and J.W. Eastwood, Computer Simulation Using Particles. IOP Publishing, 1988.
[20] A. Hoisie, O. Lubeck, and H. Wassermann, “Performance and Scalability Analysis of Teraflop-Scale Parallel Architectures Using Multidimentional Wavefront Applications,” Int'l J. High Performance Computing Applications, vol. 14, p. 330, 2000.
[21] A. Kawai, T. Fukushige, and J. Makino, “$7.0/Mflops Astrophysical $N{\hbox{-}}{\rm{Body}}$ Simulation with Treecode on GRAPE-5,” Proc. Supercomputing Conf., 1999.
[22] A. Kawai and J. Makino, “Pseudoparticle Multipole Method: A Simple Method to Implement High-Accuracy Treecode,” Astrophysical J., vol. 550, p. 143, 2001.
[23] T. Kurc, M. Uysal, H. Eom, J. Hollingsworth, J. Saltz, and A. Sussman, “Efficient Performance Prediction for Large-Scale, Data-Intensive Applications,” Int'l J. High Performance Computing Applications, vol. 14, p. 216, 2000.
[24] J. Makino, “Treecode with a Special-Purpose Processor,” Publications of the Astronomical Soc. of Japan, vol. 43, p. 621, 1991.
[25] J. Makino, “A Modified Aarseth Code for GRAPE and Vector Processors,” Publications of the Astronomical Soc. of Japan, vol. 43, p. 859, 1991.
[26] J. Makino, M. Taiji, T. Ebisuzaki, and D. Sugimoto, “GRAPE-4: A Massively Parallel Special-Purpose Computer for Collisional $N{\hbox{-}}{\rm{Body}}$ Simulations,” Astrophysical J., vol. 480, p. 432, 1997, J. Makino and M. Taiji Scientific Simulations with Special-Purpose Computers. Wiley, 1998.
[27] J. Makino and M. Taiji, “Astrophysical $N{\hbox{-}}{\rm{Body}}$ Simulations on GRAPE-4 Special-Purpose Computer,” Proc. Supercomputing Conf., 1995.
[28] J. Makino, “Yet Another Fast Multipole Method without Multipoles—Pseudoparticle Multipole Method,” J. Computational Physics, vol. 151, p. 910, 1999.
[29] J. Makino, T. Fukushige, and K. Masaki, “A 1.349 Tflops Simulation of Black Holes in a Galactic Center on GRAPE-6,” Proc. Supercomputing Conf., 2000.
[30] J. Makino and T. Fukushige, “A 11.55 Tflops Simulation of Black Holes in a Galactic Center on GRAPE-6,” Proc. Supercomputing Conf., 2001.
[31] J. Makino, E. Kokubo, T. Fukushige, and H. Daisaka, “A 22.72 Tflops Simulation of Planetesimals in Uranus-Neptune Region on GRAPE-6,” Proc. Supercomputing Conf., 2002.
[32] R.D. Mawhinney, “The 1 Teraflops QCDSP Computer,” Parallel Computing, vol. 25, p. 1281, 1999.
[33] S.L.W. McMillan and S.J. Aarseth, “An ${\cal{O}}(N \cdot\log N)$ Integration Scheme for Collisional Stellar Systems,” Astrophysical J., vol. 414, p. 200, 1993.
[34] P. Palazzari, L. Arcipiani, M. Celino, R. Guadagni, A. Marongiu, A. Mathis, P. Novelli, and V. Rosato, “Heterogeneity as Key Feature of High Performance Computing: The PQE1 Prototype,” Proc. Ninth Heterogeneous Computing Workshop, 2000.
[35] A.D. Pimentel, L.O. Hertzberger, P. Lieverse, P. van der Wolf, and E.F. Deprettere, “Exploring Embedded-Systems Architectures with Artemis,” Computer, vol. 34, no. 11, p. 57, 2001.
[36] H.C. Plummer, “The Distribution of Stars in Globular Clusters,” Monthly Notices of the Royal Astronomical Soc., vol. 76, p. 107, 1915.
[37] P.F. Spinnato, G.D. van Albada, and P.M.A. Sloot, “Performance Analysis of Parallel $N{\hbox{-}}{\rm{Body}}$ Codes,” Proc. HPCN Europe Conf., 2000.
[38] P.F. Spinnato, G.D. van Albada, and P.M.A. Sloot, “Performance Prediction of $N{\hbox{-}}{\rm{Body}}$ Simulations on a Hybrid Architecture,” Computer Physics Comm., vol. 139, p. 34, 2001.
[39] P.F. Spinnato, G.D. van Albada, and P.M.A. Sloot, “A Versatile Simulation Model for Hierarchical Treecodes,” Proc. ICCS Conf., 2002.
[40] L. Spitzer, Dynamical Evolution of Globular Clusters. Princeton Univ. Press, 1987.
[41] V. Springel, N. Yoshida, and S.D.M. White, “GADGET: A Code for Collisionless and Gasdynamical Cosmological Simulations,” New Astronomy, vol. 6, p. 79, 2001.
[42] R. Tripiccione, “APEmille,” Parallel Computing, vol. 25, p. 1297, 1999.
[43] M.S. Warren and J.K. Salmon, “A Portable Parallel Particle Program,” Computer Physics Comm., vol. 87, p. 266, 1995.

Citation:
"Editor's note," IEEE Transactions on Parallel and Distributed Systems, vol. 15, no. 1, pp. 1, Jan. 2004, doi:10.1109/TPDS.2004.1264780
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