The usefulness of the information extracted from biomedical data relies heavily on the underlying theory of the methods used in its extraction. The assumptions of stationarity and autonomicity traditionally applied to dynamical systems break down when considering living systems, due to their inherent time-variability. Living systems are thermodynamically open, and thus constantly interacting with their environment. This results in highly nonlinear, time-dependent dynamics. The aim of signal analysis is to gain insight into the behaviour of the system from which the signal originated. Here, various analysis methods for the characterization of signals and their underlying non-autonomous dynamics are presented, incorporating time-frequency ana...
This book reports on the latest advances in complex and nonlinear cardiovascular physiology aimed at...
The application of methods drawn from nonlinear and stochastic dynamics to the analysis of cardiovas...
It is known that any physiological system is capable of adapting to constantly changing environmenta...
The recent introduction of chronotaxic systems provides the means to describe nonautonomous systems ...
A new method is introduced for analysis of interactions between time-dependent coupled oscillators, ...
This book, based on a selection of invited presentations from a topical workshop, focusses on time-v...
Interacting dynamical systems abound in nature, with examples ranging from biology and population dy...
The application of methods drawn from nonlinear and stochastic dynamics to the analysis of cardiovas...
AbstractThe application of methods drawn from nonlinear and stochastic dynamics to the analysis of c...
The same periodic components are demonstrated for different functions, and at different sites, of th...
Modelling the cardiovascular system (CVS) presents a challenging and important problem. The CVS is a...
Physiological rhythms are not strictly periodic but rather fluctuate irregularly over time. Rhythms ...
The functions of the brain and cardiovascular system incorporate oscillatory processes at several ti...
The first chapter presents methods for analyzing nonstationary physiological signals. Among them ar...
Biological systems are never isolated, usually oscillatory, and invariably subject to noise and fluc...
This book reports on the latest advances in complex and nonlinear cardiovascular physiology aimed at...
The application of methods drawn from nonlinear and stochastic dynamics to the analysis of cardiovas...
It is known that any physiological system is capable of adapting to constantly changing environmenta...
The recent introduction of chronotaxic systems provides the means to describe nonautonomous systems ...
A new method is introduced for analysis of interactions between time-dependent coupled oscillators, ...
This book, based on a selection of invited presentations from a topical workshop, focusses on time-v...
Interacting dynamical systems abound in nature, with examples ranging from biology and population dy...
The application of methods drawn from nonlinear and stochastic dynamics to the analysis of cardiovas...
AbstractThe application of methods drawn from nonlinear and stochastic dynamics to the analysis of c...
The same periodic components are demonstrated for different functions, and at different sites, of th...
Modelling the cardiovascular system (CVS) presents a challenging and important problem. The CVS is a...
Physiological rhythms are not strictly periodic but rather fluctuate irregularly over time. Rhythms ...
The functions of the brain and cardiovascular system incorporate oscillatory processes at several ti...
The first chapter presents methods for analyzing nonstationary physiological signals. Among them ar...
Biological systems are never isolated, usually oscillatory, and invariably subject to noise and fluc...
This book reports on the latest advances in complex and nonlinear cardiovascular physiology aimed at...
The application of methods drawn from nonlinear and stochastic dynamics to the analysis of cardiovas...
It is known that any physiological system is capable of adapting to constantly changing environmenta...