Practical Multiscaling

Jacob Fish, Columbia University, USAJacob Fish is the Robert A. W. and Christine S. Carleton Professor in Civil Engineering at Columbia University. He is the Founder and Editor-in-Chief of the International Journal of Multiscale Computational Engineering and serves as an Associate Editor of the International Journal for Numerical Methods in Engineering. He is also on the editorial board of the Computer Methods in Applied Mechanics and Engineering, the International Journal of Computational Methods and the International Journal of Computational Engineering Science.He has has written over 160 journal articles, book chapters and has authored two previous books. Dr. Fish specializes in Multiscale Science and Engineering with applications to aerospace, automotive industry, civil engineering, biological and material sciences.

Preface 1 Chapter 1: Introduction to multiscale methods 1.1 The rationale for multiscale computations 1.2 The hype and the reality 1.3 Examples and qualification of multiscale methods 1.4 Nomenclature and definitions 1.5 Notation 2 Chapter 2: Upscaling/Downscaling of Continua 2.1 Introduction 2.2 Homogenizaton of linear heterogeneous media 2.3 Upscaling based on enhanced kinematics 2.4 Homogenization of nonlinear heterogeneous media 2.5 Higher order homogenization 2.6 Multiple-scale homogenization 2.7 Going beyond upscaling -- homogenization-based multigrid 3 Chapter 3: Upscaling/Downscaling of Atomistic/Continuum Media 3.1 Introduction 3.2 Governing equations 3.3 Generalized mathematical homogenization (GMH) 3.4 Finite element implementation and numerical verification 3.5 Statistical ensemble 3.6 Verification 3.7 Going beyond upscaling 4 Chapter 4: Reduced Order Homogenization 4.1 Introduction 4.2 Reduced order homogenization for two-scale problems 4.3 Lower order approximation of eigenstrains 4.4 Extension to nonlocal heterogeneous media 4.5 Extension to dispersive heterogeneous media 4.6 Extension to multiple spatial scales 4.7 Extension to large deformations 4.8 Extension to multiple temporal scales with application to fatigue 4.9 Extension to multiphysics problems 5 Chapter 5: Scale-separation-free Upscaling/Downscaling of Continua 5.1 Introduction 5.2 Computational continua (C2) 5.3 Reduced order computational continua (RC2) 5.4 Nonlocal quadrature in multidimensions 5.5 Model Verification 6 Chapter 6: Multiscale Design Software 6.1 Introduction 6.2 Microanalysis with MDS-Lite 6.3 Macroanalysis with MDS-Lite