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Full Description
Data-Driven Modeling & Scientific Computation: Methods for Complex Systems & Big Data is an accessible introductory-to-advanced textbook focusing on integrating scientific computing methods and algorithms with modern data analysis techniques, including basic applications of machine learning in the sciences and engineering. Its overarching goal is to develop techniques that allow for the integration of the dynamics of complex systems and big data.
This comprehensive textbook provides a survey of practical numerical solution techniques for ordinary and partial differential equations as well as algorithms for data manipulation, data-driven modelling, and machine learning. Emphasis is on the implementation of numerical schemes to practical problems in the engineering, biological, and physical sciences.
The high-level programming language python is used throughout the book to implement and develop mathematical solution strategies. One specific aim of the book is to integrate standard scientific computing methods with the burgeoning field of data analysis, machine learning and Artificial Intelligence (AI). This area of research is expanding at an incredible pace in the sciences due to the proliferation of data collection in almost every field of science.
The enormous data sets routinely encountered in the sciences now certainly give a big incentive to develop mathematical techniques and computational algorithms that help synthesize, interpret, and give meaning to the data in the context of its scientific setting. This brings together, in a self-consistent fashion, the key ideas from (i) statistics, (ii) time-frequency analysis and (iii) low-dimensional reductions in order to provide meaningful insight into the data sets one is faced with in any scientific field today, including those generated from complex dynamic systems. This is a tremendously exciting area and much of this part of the book is driven by intuitive examples of how the three areas (i)-(iii) can be used in combination to give critical insight into the fundamental workings of various problems.
Contents
Prolegomenon to modern computing Part 1. Basic computations and visualization 1: Python introduction 2: Linear systems 3: Numerical differentiation and integration 4: Curve fitting 5: Basic optimization 6: Advanced curve fitting and machine learning 7: Visualization Part 2. Differential and partial differential equations 8: Initial and boundary value problems of differential equations 9: Finite difference methods 10: Time and space stepping schemes: methods of lines 11: Spectral methods 12: Finite element methods Part 3. Computational methods for data analysis 13: Statistical methods and their applications 14: Time-frequency analysis: Fourier transforms and wavelets 15: Matrix decompositions 16: Independent component analysis 17: Unsupervised machine learning 18: Supervised machine learning 19: Reinforcement learning 20: Spatio-temporal data and dynamics 21: Data assimilation methods Bibliography Index
