Abstract
Pulse signals are widely used to evaluate the status of the human cardiovascular, respiratory, and circulatory systems. In the process of being collected, the signals are usually interfered by some factors, such as the spike noise and the poor-sensor-contact noise, which have severely affected the accuracy of the subsequent detection models. In recent years, some methods have been applied to processing the above noisy signals, such as dynamic time warping, empirical mode decomposition, autocorrelation, and cross-correlation. Effective as they are, those methods are complex and difficult to implement. It is also found that the noisy signals are tightly related to gross errors. The Chauvenet criterion, one of the gross error discrimination criterions, is highly efficient and widely applicable for being without the complex calculations like decomposition and reconstruction. Therefore, in this study, based on the Chauvenet criterion, a new pulse signal preprocessing method is proposed, in which adaptive thresholds are designed, respectively, to discriminate the abnormal signals caused by spike noise and poor-sensor-contact noise. 81 hours of pulse signals (with a sleep apnea annotated every 30 seconds and 9,720 segments in total) from the MIT-BIH Polysomnographic Database are used in the study, including 35 minutes of poor-sensor-contact noises and 25 minutes of spike noises. The proposed method was used to preprocess the pulse signals, in which 9,684 segments out of a total of 9,720 were correctly discriminated, and the accuracy of the method reached 99.63%. To quantitatively evaluate the noise removal effect, a simulation experiment is conducted to compare the Jaccard Similarity Coefficient (JSC) calculated before and after the noise removal, respectively, and the results show that the preprocessed signal obtains higher JSC, closer to the reference signal, which indicates that the proposed method can effectively improve the signal quality. In order to evaluate the method, three back-propagation (BP) sleep apnea detection models with the same network structure and parameters were established, respectively. Through comparing the recognition rate and the prediction rate of the models, higher rates were obtained by using the proposed method. To prove the efficiency, the comparison experiment between the proposed Chauvenet-based method and a Romanovsky-based method was conducted, and the execution time of the proposed method is much shorter than that of the Romanovsky method. The results suggest that the superiority in execution time of the Chauvenet-based method becomes more significant as the date size increases.
Highlights
Within each heart beat cycle, the blood vessel presents pulsatile changes in accordance with the systolic and diastolic functions of the heart, which are termed as the pulse signals [1]. ere are plenty of physiological information in pulse signals, by which some physiological parameters, such as pulse rate, blood oxygen saturation, and microcirculation, can be calculated directly or indirectly, and which can be applied to related detection models for the evaluation of the cardiovascular, respiratory, and circulatory system statuses [2,3,4]
The methods applied for removing the spike noise and the poor-sensor-contact noise are so complex that they have to use multiple iterative calculations, decompositions, reconstructions, and so on and occupy many system resources, not favorable for the subsequent related physiological parameters and the establishment of detection models. erefore, it is of great significance to adopt a simpler and more effective preprocessing method for the removal of these noises
This paper has proposed a new pulse signal preprocessing method based on the Chauvenet criterion, which is highly efficient in implementation, and is used to discriminate the noises occurring in the conditions of poor-sensor-contact and unstable switch power
Summary
Within each heart beat cycle, the blood vessel presents pulsatile changes in accordance with the systolic and diastolic functions of the heart, which are termed as the pulse signals [1]. ere are plenty of physiological information in pulse signals, by which some physiological parameters, such as pulse rate, blood oxygen saturation, and microcirculation, can be calculated directly or indirectly, and which can be applied to related detection models for the evaluation of the cardiovascular, respiratory, and circulatory system statuses [2,3,4]. Li and Clifford [7] proposed a PPG signal preprocessing algorithm based on dynamic time warping (DTW), which evaluated the signal quality by means of analyzing the characteristics related to signal quality through a multilayer perception neural network. Ey selected the specific components to reconstruct the signals and extracted important features in the original signals by applying multiscale filter and accumulated energy contribution rate filter to the components that were obtained from decomposition, resolving the problem of breaks in the dynamic pulse signals, namely, the problem of poor-sensor-contact. The methods applied for removing the spike noise and the poor-sensor-contact noise are so complex that they have to use multiple iterative calculations, decompositions, reconstructions, and so on and occupy many system resources, not favorable for the subsequent related physiological parameters and the establishment of detection models. The methods applied for removing the spike noise and the poor-sensor-contact noise are so complex that they have to use multiple iterative calculations, decompositions, reconstructions, and so on and occupy many system resources, not favorable for the subsequent related physiological parameters and the establishment of detection models. erefore, it is of great significance to adopt a simpler and more effective preprocessing method for the removal of these noises
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