Abstract
This paper shows how the dynamics of the PhotoPlethysmoGraphic (PPG) signal, an easily accessible biological signal from which valuable diagnostic information can be extracted, of young and healthy individuals performs at different timescales. On a small timescale, the dynamic behavior of the PPG signal is predominantly quasi-periodic. On a large timescale, a more complex dynamic diversity emerges, but never a chaotic behavior as earlier studies had reported. The procedure by which the dynamics of the PPG signal is determined consists of contrasting the dynamics of a PPG signal with well-known dynamics---named reference signals in this study---, mostly present in physical systems, such as periodic, quasi-periodic, aperiodic, chaotic or random dynamics. For this purpose, this paper provides two methods of analysis based on Deep Neural Network (DNN) architectures. The former uses a Convolutional Neural Network (CNN) architecture model. Upon training with reference signals, the CNN model identifies the dynamics present in the PPG signal at different timescales, assigning, according to a classification process, an occurrence probability to each of them. The latter uses a Recurrent Neural Network (RNN) based on a Long Short-Term Memory (LSTM) architecture. With each of the signals, whether reference signals or PPG signals, the RNN model infers an evolution function (nonlinear regression model) based on training data, and considers its predictive capability over a relatively short time horizon.
Highlights
Even in ancient times, medical specialists paid particular attention to human physiology, since understanding the mechanisms that make it possible for the human body to function correctly opened up a new avenue in development diagnostic procedures to possible pathologies or more and less severe somatic disorders [1]
DYNAMIC BEHAVIOR CLASSIFICATION WITH A Convolutional Neural Network (CNN) MODEL Here we show the evaluation of our implemented CNN-based dynamic behavior classification system using a real-world PPG signals dataset, consisting of 40 PPG signals from young and healthy individuals between the ages of 18 and 30, according to a national research project, and reference signals of well-known dynamics
The rationale for defining different timescales is that the dynamic behavior differs considerably on the PPG signal as we introduce more and more signal cycles, allowing us to discover the hidden dynamic richness of the PPG signal that we cannot appreciate at small timescales
Summary
Medical specialists paid particular attention to human physiology, since understanding the mechanisms that make it possible for the human body to function correctly opened up a new avenue in development diagnostic procedures to possible pathologies or more and less severe somatic disorders [1]. Physiological systems are dissipative systems that, in their energy exchange with the surrounding environment, ensure the stability of the homeostatic process, an internal self-regulatory mechanism that guarantees optimal vital conditions [2]. This interrelation is best reflected by dynamic variables that can be measured directly or indirectly using the appropriate technical equipment. Dynamic variables are known in medical jargon as. It is not always possible to measure all the dynamic variables involved in physiological functioning; at best, only a few, the so-called physical observables, are available. It is practically possible to gain information on the state of the system using only one dynamic variable [3]
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