[1] Farmer, J.R., Martinelli, L., and Jameson, A., “A Fast Multigrid Method for Solving the Nonlinear Ship Wave Problem with a Free Surface,” Proceedings, Sixth International Conference on Numerical Ship Hydrodynamics, pp. 155–172, 1993.

[2] Farmer, J.R., Martinelli, L., and Jameson, A., “A Fast Multigrid Method for Solving Incompressible Hydrodynamic Problems with Free Surfaces,” AIAA Journal, v. 32, no. 6, pp. 1175–1182, 1994.

[3] Jameson, A., “Optimum Aerodynamic Design Using CFD and Control Theory,” Proceedings, 12th Computational Fluid Dynamics Conference, San Diego, California, 1995

[4] Jameson, A., “A Vertex Based Multigrid Algorithm For Three Dimensional Compressible Flow Calculations,” ASME Symposium on Numerical Methods for Compressible Flows, Annaheim, December 1986.

[5] Baldwin, B.S., and Lomax, H., “Thin Layer Approximation and Algebraic Model for Separated Turbulent Flows,” AIAA Paper 78–257, AIAA 16th Aerospace Sciences Meeting, Reno, NV, January 1978.

[6] Chorin, A., “A Numerical Method for Solving Incompressible Viscous Flow Problems,” Journal of Computational Physics, v. 2, pp. 12–26, 1967.

[7] Rizzi, A., and Eriksson,L., “Computation of Inviscid Incompressible Flow with Rotation,” Journal of Fluid Mechanics, v. 153, pp. 275–312, 1985.

[8] Martinelli, L., “Calculations of Viscous Flows with a Multigrid Method,” Ph.D. Thesis, MAE 1754-T, Princeton University, 1987.

[9] Farmer, J., “A Finite Volume Multigrid Solution to the Three Dimensional Nonlinear Ship Wave Problem,” Ph.D. Thesis, MAE 1949-T, Princeton University, January 1993.

[10] A.Jameson, “Analysis and design of numerical schemes for gas dynamics 1, artificial diffusion, upwind biasing, limiters and their effect on multigrid convergence,” Int. J. of Comp. Fluid Dyn., To Appear.

[11] A.Jameson, “Analysis and design of numerical schemes for gas dynamics 2, artificial diffusion and discrete shock structure,” Int. J. of Comp. Fluid Dyn., To Appear.

[12] J.Farmer, L.Martinelli, A.Jameson, and G.Cowles, “Fully-nonlinear CFD techniques for ship performance analysis and design,” AIAA paper 95–1690, AIAA 12th Computational Fluid Dynamics Conference, San Diego, CA, June 1995.

[13] A.Jameson, “Multigrid algorithms for compressible flow calculations,” In Second European Conference on Multigrid Methods , Cologne, October 1985. Princeton University Report MAE 1743.

[14] L.Martinelli and A.Jameson, “Validation of a multigrid method for the Reynolds averaged equations,” AIAA paper 88–0414, 1988.

[15] L.Martinelli, A.Jameson, and E.Malfa, “Numerical simulation of three-dimensional vortex flows over delta wing configurations,” In M.Napolitano and F.Sabbetta, editors, Proc. 13th International Conference on Numerical Methods in Fluid Dynamics, pages 534–538, Rome, Italy, July 1992. Springer Verlag, 1993.

[16] F.Liu and A.Jameson, “Multigrid Navier-Stokes calculations for three-dimensional cascades,” AIAA paper 92–0190, AIAA 30th Aerospace Sciences Meeting, Reno, Nevada, January 1992.

[17] G.Cowles, and L.Martinelli “Fully Nonlinear Hydrodynamic Calculations for Ship Design on Parallel Computing Platforms,” Proc. 21st International Symposium on Naval Hydrodynamics, Trondheim, Norway, June 1996

[18] G.Cowles, and L.Martinelli “A Cell-Centered Parallel Multiblock Method for Viscous Incompressible Flows with a Free Surface,” Proc. 13th AIAA Computational Fluid Dynamics Conference, Snowmass, Colorado, July 1997

[19] Y.Toda, F.Stern, and J.Longo “Mean-Flow Measurements in the Boundary Layer and Wake and Wave Field of a Series 60 Cb=.6 Ship Model for Froude Numbers .16 and .316 IIHR Report No. 352, Iowa Institute of Hydraulic Research, August 1991

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