Physics-Based Learning Models for Ship Hydrodynamics.

We present the concepts of physics-based learning models (PBLM) and their relevance and application to the field of ship hydrodynamics. The utility of physics-based learning is motivated by contrasting generic learning models for regression predictions, which do not presume any knowledge of the system other than the training data provided with methods such as semi-empirical models, which incorporate physical insights along with data-fitting. PBLM provides a framework wherein intermediate models, which capture (some) physical aspects of the problem, are incorporated into modern generic learning tools to substantially improve the predictions of the latter, minimizing the reliance on costly experimental measurements or high-resolution highfidelity numerical solutions. To illustrate the versatility and efficacy of PBLM, we present three wave-ship interaction problems: 1) at speed waterline profiles; 2) ship motions in head seas; and 3) three-dimensional breaking bow waves. PBLM is shown to be robust and produce error rates at or below the uncertainty in the generated data at a small fraction of the expense of high-resolution numerical predictions

[1]  Alexander J. Smola,et al.  Learning with Kernels: support vector machines, regularization, optimization, and beyond , 2001, Adaptive computation and machine learning series.

[2]  R. E. Kalman,et al.  A New Approach to Linear Filtering and Prediction Problems , 2002 .

[3]  Gene H. Golub,et al.  Generalized cross-validation as a method for choosing a good ridge parameter , 1979, Milestones in Matrix Computation.

[4]  Paul S. Granville,et al.  DRAG AND TURBULENT BOUNDARY LAYER OF FLAT PLATES AT LOW REYNOLDS NUMBERS , 1975 .

[5]  Vladimir N. Vapnik,et al.  The Nature of Statistical Learning Theory , 2000, Statistics for Engineering and Information Science.

[6]  Christopher J. C. Burges,et al.  A Tutorial on Support Vector Machines for Pattern Recognition , 1998, Data Mining and Knowledge Discovery.

[7]  Dick K. P. Yue,et al.  Boundary data immersion method for Cartesian-grid simulations of fluid-body interaction problems , 2011, J. Comput. Phys..

[8]  Gabriel Weymouth,et al.  Advancements in Cartesian-grid methods for computational ship hydrodynamics , 2006 .

[9]  Dick K. P. Yue,et al.  Numerical Solutions for Large-Amplitude Ship Motions in the Time Domain , 1991 .

[10]  F. Stern,et al.  Ship motions using single-phase level set with dynamic overset grids , 2007 .

[11]  Emmanuel Fontaine,et al.  A slender body approach to nonlinear bow waves , 1997, Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences.

[12]  W. Faller,et al.  Simulation of Ship Maneuvers Using Recursive Neural Networks , 2006 .

[13]  Bernhard Schölkopf,et al.  New Support Vector Algorithms , 2000, Neural Computation.

[14]  F. Stern,et al.  RANS Computational Fluid Dynamics Predictions of Pitch and Heave Ship Motions in Head Seas , 2005 .

[15]  Tomaso A. Poggio,et al.  Regularization Networks and Support Vector Machines , 2000, Adv. Comput. Math..

[16]  Geir Evensen,et al.  The Ensemble Kalman Filter: theoretical formulation and practical implementation , 2003 .

[17]  S. Wood Thin plate regression splines , 2003 .

[18]  Johan M.J. Journee,et al.  Experiments and calculations on Four Wigley Hullforms , 1992 .

[19]  Tomaso A. Poggio,et al.  Regularization Theory and Neural Networks Architectures , 1995, Neural Computation.

[20]  N. M. Alexandrov,et al.  A trust-region framework for managing the use of approximation models in optimization , 1997 .

[21]  D.G. Dommermuth,et al.  Modeling Breaking Ship Waves for Design and Analysis of Naval Vessels , 2007, 2007 DoD High Performance Computing Modernization Program Users Group Conference.

[22]  John L Hess,et al.  CALCULATION OF NON-LIFTING POTENTIAL FLOW ABOUT ARBITRARY THREE-DIMENSIONAL BODIES , 1962 .

[23]  P. A. Newman,et al.  Approximation and Model Management in Aerodynamic Optimization with Variable-Fidelity Models , 2001 .

[24]  S. Wood,et al.  Generalized Additive Models: An Introduction with R , 2006 .

[25]  David E. Hess,et al.  Real-Time Simulation Based Design Part II: Changes in Hull Geometry , 2006 .