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This book introduces readers to mobile information services for
networks. The content is divided into eight chapters, each of which
presents a specific concept and the latest related developments in
mobile information services. Mobile information services for
networks can be defined as platform-independent functional entities
that provide various services based on the communication network
platform. The book discusses the three main supporting technologies
for mobile information services: neighbor discovery in the data
link layer; routing and balanced association in the network layer;
and community structure detection in the application layer. Lastly,
the book describes the development of applications based on the
authors' mobile information service platform, as well as related
key technologies in the domains of intelligent transportation,
smart tourism, and mobile payment, such as trajectory analysis,
location recommendation, and mobile behavior authentication, which
are promoting the development of mobile information services. This
book offers a valuable reference guide for researchers in the field
of computer science and technology, as well as those in the field
of network mobile information service technology.
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Recent Advances in Nonlinear Dynamics and Synchronization - With Selected Applications in Electrical Engineering, Neurocomputing, and Transportation (Hardcover, 1st ed. 2018)
Kyandoghere Kyamakya, Wolfgang Mathis, Ruedi Stoop, Jean Chamberlain Chedjou, Zhong Li
|
R4,753
R3,468
Discovery Miles 34 680
Save R1,285 (27%)
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Ships in 12 - 17 working days
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This book focuses on modelling and simulation, control and
optimization, signal processing, and forecasting in selected
nonlinear dynamical systems, presenting both literature reviews and
novel concepts. It develops analytical or numerical approaches,
which are simple to use, robust, stable, flexible and universally
applicable to the analysis of complex nonlinear dynamical systems.
As such it addresses key challenges are addressed, e.g. efficient
handling of time-varying dynamics, efficient design, faster
numerical computations, robustness, stability and convergence of
algorithms. The book provides a series of contributions discussing
either the design or analysis of complex systems in sciences and
engineering, and the concepts developed involve nonlinear dynamics,
synchronization, optimization, machine learning, and forecasting.
Both theoretical and practical aspects of diverse areas are
investigated, specifically neurocomputing, transportation
engineering, theoretical electrical engineering, signal processing,
communications engineering, and computational intelligence. It is a
valuable resource for students and researchers interested in
nonlinear dynamics and synchronization with applications in
selected areas.
Research and application of impedance network converters are very
popular in recent years, but it still lacks of understanding of and
guidelines of impedance networks application, therefore, there is
quiet a large potential market about impedance networks converters.
This book can serve as a teaching material for graduates and
guidelines for engineers as designing an impedance source
converter. The main purpose of this book is to understand impedance
networks of nonlinear switch circuits and impedance networks
matching, which will further put forward understanding of all power
converters in view of impedance networks. Taking the impedance
network matchings into account leads to a set of criteria for
designing an impedance source converter, which is to replace the
traditional tedious, manual and experience-dependent design
methods.
This book contains a collection of recent advanced contributions in
the field of nonlinear dynamics and synchronization, including
selected applications in the area of theoretical electrical
engineering. The present book is divided into twenty-one chapters
grouped in five parts. The first part focuses on theoretical issues
related to chaos and synchronization and their potential
applications in mechanics, transportation, communication and
security. The second part handles dynamic systems modelling and
simulation with special applications to real physical systems and
phenomena. The third part discusses some fundamentals of
electromagnetics (EM) and addresses the modelling and simulation in
some real physical electromagnetic scenarios. The fourth part
mainly addresses stability concerns. Finally, the last part
assembles some sample applications in the area of optimization,
data mining, pattern recognition and image processing.
The 1960s were perhaps a decade of confusion, when scientists faced
d- culties in dealing with imprecise information and complex
dynamics. A new set theory and then an in?nite-valued logic of Lot?
A. Zadeh were so c- fusing that they were called fuzzy set theory
and fuzzy logic; a deterministic system found by E. N. Lorenz to
have random behaviours was so unusual that it was lately named a
chaotic system. Just like irrational and imaginary numbers,
negative energy, anti-matter, etc., fuzzy logic and chaos were gr-
ually and eventually accepted by many, if not all, scientists and
engineers as fundamental concepts, theories, as well as
technologies. In particular, fuzzy systems technology has achieved
its maturity with widespread applications in many industrial,
commercial, and technical ?elds, ranging from control, automation,
and arti?cial intelligence to image/signal processing,
patternrecognition, andelectroniccommerce.Chaos, ontheother hand,
wasconsideredoneofthethreemonumentaldiscoveriesofthetwentieth
century together with the theory of relativity and quantum
mechanics. As a very special nonlinear dynamical phenomenon, chaos
has reached its current outstanding status from being merely a
scienti?c curiosity in the mid-1960s to an applicable technology in
the late 1990s. Finding the intrinsic relation between fuzzy logic
and chaos theory is
certainlyofsigni?cantinterestandofpotentialimportance.Thepast20years
have indeed witnessed some serious explorations of the interactions
between fuzzylogicandchaostheory,
leadingtosuchresearchtopicsasfuzzymodeling of chaotic systems using
Takagi-Sugeno models, linguistic descriptions of chaotic systems,
fuzzy control of chaos, and a combination of fuzzy control
technology and chaos theory for various engineering pract
Contents: Equations-solving and Theorems-proving Zero-set
Formulation and Ideal Formulation (W-T Wu); Theory of Computation
and Complex Analytic Dynamics (C T Chong); Affine Geometry in
Complex Function Spaces and Algebras (A J Ellis); Some Results on
Chromatically Unique Graphs (K M Koh & C P Teo); On the
Decomposition of 0-Simple Dual Semigroups (C K Lai & K P Shum);
On the Geometry of Infinite Dimensional Teichmuller Spaces (Z Li);
Analytic Functionals and Their Transformations (M Morimoto); Groups
and Designs (C E Praeger); Global Small Solutions to Nonlinear
Evolution Equations (R Racke); and other papers;
Concerns about natural resource scarcity, together with the
increased awareness of environmental problems, has led to
widespread interest in green accounting, which attempts to extend
the standard national accounts to include the yields from natural
and environmental resources. For this volume, Professors Lofgren
and Li have selected the classic articles in this rapidly growing
area, with particular reference to sustainability. They have also
written an authoritative new introduction which offers a
comprehensive overview of the literature both from a historical and
a formal theoretical perspective. This volume will be an invaluable
reference source for scholars and practitioners seeking an in-depth
understanding of the main issues in this important field.
In essence, the dynamics of real world systems (i.e. engineered
systems, natural systems, social systesms, etc.) is nonlinear. The
analysis of this nonlinear character is generally performed through
both observational and modeling processes aiming at deriving
appropriate models (mathematical, logical, graphical, etc.) to
simulate or mimic the spatiotemporal dynamics of the given systems.
The complex intrinsic nature of these systems (i.e. nonlinearity
and spatiotemporal dynamics) can lead to striking dynamical
behaviors such as regular or irregular, stable or unstable,
periodicity or multi-periodicity, torus or chaotic dynamics. The
various potential applications of the knowledge about such dynamics
in technical sciences (engineering) are being intensively
demonstrated by diverse ongoing research activities worldwide.
However, both the modeling and the control of the nonlinear
dynamics in a range of systems is still not yet well-understood
(e.g. system models with time varying coefficients, immune systems,
swarm intelligent systems, chaotic and fractal systems, stochastic
systems, self-organized systems, etc.). This is due amongst others
to the challenging task of establishing a precise and systematic
fundamental or theoretical framework (e.g. methods and tools) to
analyze, understand, explain and predict the nonlinear dynamical
behavior of these systems, in some cases even in real-time. The
full insight in systems' nonlinear dynamic behavior is generally
achieved through approaches involving analytical, numerical and/or
experimental methods.
This book presents the fundamental concepts of fuzzy logic and
fuzzy control, chaos theory and chaos control. It also provides a
definition of chaos on the metric space of fuzzy sets. The book
raises many questions and generates a great potential to attract
more attention to combine fuzzy systems with chaos theory. In this
way it contains important seeds for future scientific research and
engineering applications.
Metamaterials: Beyond Crystals, Noncrystals, and Quasicrystals is a
comprehensive and updated research monograph that focuses on recent
advances in metamaterials based on the effective medium theory in
microwave frequencies. Most of these procedures were conducted in
the State Key Laboratory of Millimeter Waves, Southeast University,
China. The book conveys the essential concept of metamaterials from
the microcosmic structure to the macroscopic electromagnetic
properties and helps readers quickly obtain needed skills in
creating new devices at microwave frequencies using metamaterials.
The authors present the latest progress on metamaterials and
transformation optics and provide abundant examples of
metamaterial-based devices accompanied with detailed procedures to
simulate, fabricate, and measure them. Comprised of ten chapters,
the book comprehensively covers both the fundamentals and the
applications of metamaterials. Along with an introduction to the
subject, the first three chapters discuss effective medium theory
and artificial particles. The next three chapters cover homogeneous
metamaterials (super crystals), random metamaterials (super
noncrystals), and inhomogeneous metamaterials (super
quasicrystals). The final four chapters examine gradient-index
inhomogeneous metamaterials, nearly isotropic inhomogeneous
metamaterials, and anisotropic inhomogeneous metamaterials, after
which the authors provide their conclusions and closing remarks.
The book is completely self-contained, making it easy to follow.
This volume presents the proceedings of the Seventh International
Colloquium on Finite or Infinite Dimensional Complex Analysis held
in Fukuoka, Japan. The contributions offer multiple perspectives
and numerous research examples on complex variables, Clifford
algebra variables, hyperfunctions and numerical analysis.
Metamaterials, including their two-dimensional counterparts, are
composed of subwavelength-scale artificial particles. These
materials have novel electromagnetic properties, and can be
artificially tailored for various applications. Based on
metamaterials and metasurfaces, many abnormal physical phenomena
have been realized, such as negative refraction, invisible
cloaking, abnormal reflection and focusing, and many new functions
and devices have been developed. The effective medium theory lays
the foundation for design and application of metamaterials and
metasurfaces, connecting metamaterials with real world
applications. In this Element, the authors combine these essential
ingredients, and aim to make this Element an access point to this
field. To this end, they review classical theories for dielectric
functions, effective medium theory, and effective parameter
extraction of metamaterials, also introducing front edge
technologies like metasurfaces with theories, methods, and
potential applications. Energy densities are also included.
This book introduces readers to mobile information services for
networks. The content is divided into eight chapters, each of which
presents a specific concept and the latest related developments in
mobile information services. Mobile information services for
networks can be defined as platform-independent functional entities
that provide various services based on the communication network
platform. The book discusses the three main supporting technologies
for mobile information services: neighbor discovery in the data
link layer; routing and balanced association in the network layer;
and community structure detection in the application layer. Lastly,
the book describes the development of applications based on the
authors' mobile information service platform, as well as related
key technologies in the domains of intelligent transportation,
smart tourism, and mobile payment, such as trajectory analysis,
location recommendation, and mobile behavior authentication, which
are promoting the development of mobile information services. This
book offers a valuable reference guide for researchers in the field
of computer science and technology, as well as those in the field
of network mobile information service technology.
Research and application of impedance network converters are very
popular in recent years, but it still lacks of understanding of and
guidelines of impedance networks application, therefore, there is
quiet a large potential market about impedance networks converters.
This book can serve as a teaching material for graduates and
guidelines for engineers as designing an impedance source
converter. The main purpose of this book is to understand impedance
networks of nonlinear switch circuits and impedance networks
matching, which will further put forward understanding of all power
converters in view of impedance networks. Taking the impedance
network matchings into account leads to a set of criteria for
designing an impedance source converter, which is to replace the
traditional tedious, manual and experience-dependent design
methods.
This book focuses on modelling and simulation, control and
optimization, signal processing, and forecasting in selected
nonlinear dynamical systems, presenting both literature reviews and
novel concepts. It develops analytical or numerical approaches,
which are simple to use, robust, stable, flexible and universally
applicable to the analysis of complex nonlinear dynamical systems.
As such it addresses key challenges are addressed, e.g. efficient
handling of time-varying dynamics, efficient design, faster
numerical computations, robustness, stability and convergence of
algorithms. The book provides a series of contributions discussing
either the design or analysis of complex systems in sciences and
engineering, and the concepts developed involve nonlinear dynamics,
synchronization, optimization, machine learning, and forecasting.
Both theoretical and practical aspects of diverse areas are
investigated, specifically neurocomputing, transportation
engineering, theoretical electrical engineering, signal processing,
communications engineering, and computational intelligence. It is a
valuable resource for students and researchers interested in
nonlinear dynamics and synchronization with applications in
selected areas.
This book contains a collection of recent advanced contributions in
the field of nonlinear dynamics and synchronization, including
selected applications in the area of theoretical electrical
engineering. The present book is divided into twenty-one chapters
grouped in five parts. The first part focuses on theoretical issues
related to chaos and synchronization and their potential
applications in mechanics, transportation, communication and
security. The second part handles dynamic systems modelling and
simulation with special applications to real physical systems and
phenomena. The third part discusses some fundamentals of
electromagnetics (EM) and addresses the modelling and simulation in
some real physical electromagnetic scenarios. The fourth part
mainly addresses stability concerns. Finally, the last part
assembles some sample applications in the area of optimization,
data mining, pattern recognition and image processing.
In essence, the dynamics of real world systems (i.e. engineered
systems, natural systems, social systesms, etc.) is nonlinear. The
analysis of this nonlinear character is generally performed through
both observational and modeling processes aiming at deriving
appropriate models (mathematical, logical, graphical, etc.) to
simulate or mimic the spatiotemporal dynamics of the given systems.
The complex intrinsic nature of these systems (i.e. nonlinearity
and spatiotemporal dynamics) can lead to striking dynamical
behaviors such as regular or irregular, stable or unstable,
periodicity or multi-periodicity, torus or chaotic dynamics. The
various potential applications of the knowledge about such dynamics
in technical sciences (engineering) are being intensively
demonstrated by diverse ongoing research activities worldwide.
However, both the modeling and the control of the nonlinear
dynamics in a range of systems is still not yet well-understood
(e.g. system models with time varying coefficients, immune systems,
swarm intelligent systems, chaotic and fractal systems, stochastic
systems, self-organized systems, etc.). This is due amongst others
to the challenging task of establishing a precise and systematic
fundamental or theoretical framework (e.g. methods and tools) to
analyze, understand, explain and predict the nonlinear dynamical
behavior of these systems, in some cases even in real-time. The
full insight in systems' nonlinear dynamic behavior is generally
achieved through approaches involving analytical, numerical and/or
experimental methods.
The 1960s were perhaps a decade of confusion, when scientists faced
d- culties in dealing with imprecise information and complex
dynamics. A new set theory and then an in?nite-valued logic of Lot?
A. Zadeh were so c- fusing that they were called fuzzy set theory
and fuzzy logic; a deterministic system found by E. N. Lorenz to
have random behaviours was so unusual that it was lately named a
chaotic system. Just like irrational and imaginary numbers,
negative energy, anti-matter, etc., fuzzy logic and chaos were gr-
ually and eventually accepted by many, if not all, scientists and
engineers as fundamental concepts, theories, as well as
technologies. In particular, fuzzy systems technology has achieved
its maturity with widespread applications in many industrial,
commercial, and technical ?elds, ranging from control, automation,
and arti?cial intelligence to image/signal processing,
patternrecognition, andelectroniccommerce.Chaos, ontheother hand,
wasconsideredoneofthethreemonumentaldiscoveriesofthetwentieth
century together with the theory of relativity and quantum
mechanics. As a very special nonlinear dynamical phenomenon, chaos
has reached its current outstanding status from being merely a
scienti?c curiosity in the mid-1960s to an applicable technology in
the late 1990s. Finding the intrinsic relation between fuzzy logic
and chaos theory is
certainlyofsigni?cantinterestandofpotentialimportance.Thepast20years
have indeed witnessed some serious explorations of the interactions
between fuzzylogicandchaostheory,
leadingtosuchresearchtopicsasfuzzymodeling of chaotic systems using
Takagi-Sugeno models, linguistic descriptions of chaotic systems,
fuzzy control of chaos, and a combination of fuzzy control
technology and chaos theory for various engineering pract
Metamaterials: Beyond Crystals, Noncrystals, and Quasicrystals is a
comprehensive and updated research monograph that focuses on recent
advances in metamaterials based on the effective medium theory in
microwave frequencies. Most of these procedures were conducted in
the State Key Laboratory of Millimeter Waves, Southeast University,
China. The book conveys the essential concept of metamaterials from
the microcosmic structure to the macroscopic electromagnetic
properties and helps readers quickly obtain needed skills in
creating new devices at microwave frequencies using metamaterials.
The authors present the latest progress on metamaterials and
transformation optics and provide abundant examples of
metamaterial-based devices accompanied with detailed procedures to
simulate, fabricate, and measure them. Comprised of ten chapters,
the book comprehensively covers both the fundamentals and the
applications of metamaterials. Along with an introduction to the
subject, the first three chapters discuss effective medium theory
and artificial particles. The next three chapters cover homogeneous
metamaterials (super crystals), random metamaterials (super
noncrystals), and inhomogeneous metamaterials (super
quasicrystals). The final four chapters examine gradient-index
inhomogeneous metamaterials, nearly isotropic inhomogeneous
metamaterials, and anisotropic inhomogeneous metamaterials, after
which the authors provide their conclusions and closing remarks.
The book is completely self-contained, making it easy to follow.
This volume presents the proceedings of the Seventh International
Colloquium on Finite or Infinite Dimensional Complex Analysis held
in Fukuoka, Japan. The contributions offer multiple perspectives
and numerous research examples on complex variables, Clifford
algebra variables, hyperfunctions and numerical analysis.
|
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