1st Edition
Fractal Patterns in Nonlinear Dynamics and Applications
Most books on fractals focus on deterministic fractals as the impact of incorporating randomness and time is almost absent. Further, most review fractals without explaining what scaling and self-similarity means. This book introduces the idea of scaling, self-similarity, scale-invariance and their role in the dimensional analysis. For the first time, fractals emphasizing mostly on stochastic fractal, and multifractals which evolves with time instead of scale-free self-similarity, are discussed. Moreover, it looks at power laws and dynamic scaling laws in some detail and provides an overview of modern statistical tools for calculating fractal dimension and multifractal spectrum.
Preface
Scaling, Scale-invariance and Self-similarity
Dimensions of physical quantity
Buckingham Pi-theorem
Examples to illustrate significance of P-theorem
Similarity
Self-similarity
Dynamic scaling
Scale-invariance: Homogeneous function
Power-law distribution
Fractals
Introduction
Euclidean geometry
Fractals
Space of Fractal
Construction of deterministic fractals
Stochastic Fractal
Introduction
A brief description of stochastic process
Dyadic Cantor set (DCS): Random fractal
Kinetic Dyadic Cantor set
Stochastic dyadic Cantor set
Numerical Simulation
Stochastic fractal in aggregation with stochastic self-replication
Discussion and summary
Multifractality
Introduction
The Legendre transformation
Theory of multifractality
Multifractal formalism in fractal
Cut and paste model on Sierpinski carpet
Stochastic multifractal
Weighted planar stochastic lattice model
Algorithm of the weighted planar stochastic lattice (WPSL)
Geometric properties of WPSL
Geometric properties of WPSL
Multifractal formalism in kinetic square lattice
Fractal and Multifractal in Stochastic Time Series
Introduction
Concept of scaling law, monofractal and multifractal time series
Stationary and Non-stationary time series
Fluctuation analysis on monofractal stationary and non-stationary time series
Fluctuation analysis on stationary and non-stationary multifractal time series
Discussion
Application in Image Processing
Introduction
Generalized fractal dimensions
Image thresholding
Performance analysis
Medical image processing
Mid-sagittal plane detection
References
Biography
Santo Banerjee was a senior research associate in the Department of Mathematics, Politecnico di Torino, Italy from 2009-2011. He is now working in the Institute for Mathematical Research, University Putra Malaysia (UPM), and is also a founder member of the Malaysia-Italy Centre of Excellence in Mathematical Science, UPM, Malaysia. His research is mainly concerned with Nonlinear Dynamics, Chaos, Complexity and Secure Communication. He is a Managing Editor of The European Physical Journal Plus.
M K Hassan obtained a PhD from Brunel University, Uxbridge, London in 1997. He was a Humboldt research fellow from 2000-2001 and worked at Potsdam University, Germany. He is a senior professor in the Department of Physics, Dhaka University, Bangladesh currently. His primary research interests consist of problems which are far from equilibrium. In particular, he is involved in the study of a number of non-equilibrium phenomena, including theory of percolation under phase transition and critical phenomena, complex network theory, worked rigorously on stochastic fractals and multifractals, complex network theory, kinetics of aggregation and fragmentation, monolayer growth by deposition, nucleation and growth processes. The concept of symmetry, order, scaling, similarity and self-similarity, dynamic and finite-size scaling, fractal, multifractal, power-law, data-collapse, etc. have been the key tools of his research.
Sayan Mukherjee is working as Assistant Professor of Mathematics at Sivanath Shastri College, University of Calcutta, India. He has authored about 40 scientific papers in reputed journals and proceedings of the conferences and book chapters. His research interests include nonlinear time series analysis, biomedical and music signals, complexity analysis.
A Gowrisankar received his PhD (2017) degrees in Mathematics from the Gandhigram Rural Institute (Deemed to be University), Tamil Nadu, India. Further, he got institute postdoctoral fellowship from Indian Institute of Technology Guwahati, India. At present, he working as Assistant Professor in the Department of Mathematics, Vellore Institute of Technology, Vellore, India. His broad area of research includes fractal analysis, image processing and fractional calculus of fractal functions.