Symmetry in Complex Network Systems Connecting Equivariant Bifurcation Theory with Engineering Applications

This book bridges the current gap between the theory of symmetry-based dynamics and its application to model and analyze complex systems. As an alternative approach, the authors use the symmetry of the system directly to formulate the appropriate models, and also to analyze the dynamics. Complex sys...

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Bibliographic Details
Main Authors: In, Visarath, Palacios, Antonio (Author)
Format: eBook
Language:English
Published: Berlin, Heidelberg Springer Berlin Heidelberg 2018, 2018
Edition:1st ed. 2018
Series:Understanding Complex Systems
Subjects:
Online Access:
Collection: Springer eBooks 2005- - Collection details see MPG.ReNa
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245 0 0 |a Symmetry in Complex Network Systems  |h Elektronische Ressource  |b Connecting Equivariant Bifurcation Theory with Engineering Applications  |c by Visarath In, Antonio Palacios 
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300 |a XV, 406 p. 259 illus., 112 illus. in color  |b online resource 
505 0 |a A Unifying Theme -- Coupled-Core Fluxgate Magnetometer -- Microelectric Field Sensor -- Superconductive Quantum Interference Devices (SQUID) -- Frequency Conversion -- ANIBOT: Biologically-Inspired Animal Robot -- Gyroscope Systems -- Energy Harvesting -- Spin Torque Nano Oscillators -- Precision Timing -- References 
653 |a Mechanics, Applied 
653 |a Complex Systems 
653 |a Dynamical Systems 
653 |a Applied Dynamical Systems 
653 |a Multibody Systems and Mechanical Vibrations 
653 |a System theory 
653 |a Vibration 
653 |a Nonlinear theories 
653 |a Mathematical physics 
653 |a Multibody systems 
653 |a Theoretical, Mathematical and Computational Physics 
653 |a Dynamical systems 
653 |a Dynamics 
700 1 |a Palacios, Antonio  |e [author] 
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490 0 |a Understanding Complex Systems 
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520 |a This book bridges the current gap between the theory of symmetry-based dynamics and its application to model and analyze complex systems. As an alternative approach, the authors use the symmetry of the system directly to formulate the appropriate models, and also to analyze the dynamics. Complex systems with symmetry arise in a wide variety of fields, including communication networks, molecular dynamics, manufacturing businesses, ecosystems, underwater vehicle dynamics, celestial and spacecraft dynamics and continuum mechanics. A general approach for their analysis has been to derive a detailed model of their individual parts, connect the parts and note that the system contains some sort of symmetry, then attempt to exploit this symmetry in order to simplify numerical computations. This approach can result in highly complicated models that are difficult to analyze even numerically. The alternative approach, while nonstandard, is not entirely new among the mathematics community. However, there is much less familiarity with the techniques of symmetry-breaking bifurcation, as they apply to the engineering, design and fabrication, of complex systems, in particular, nonlinear sensor devices with special emphasis on the conceptualization and development of new technologies of magnetic sensors such as fluxgate magnetometers and SQUID (Superconducting Quantum Interference Devices), E-- (electric-field) sensors, and communication and navigation systems that require multiple frequencies of operation, such as radar and antenna devices as well as gyroscopic systems