期刊
BIOMEDICAL SIGNAL PROCESSING AND CONTROL
卷 89, 期 -, 页码 -出版社
ELSEVIER SCI LTD
DOI: 10.1016/j.bspc.2023.105700
关键词
Adventitious Lung Sounds; Signal Decomposition; Variational Mode Decomposition; Pool Adjacent Violators
This study proposes an efficient adaptive variational mode decomposition algorithm for the extraction of adventitious lung sounds from original lung sounds. The algorithm, which constructs a frequency-constrained model and employs a strategy of gradually extracting each mode, demonstrates superiority in both decomposition quality and computational efficiency. The characteristic frequency distribution of adventitious lung sounds obtained from the experiment results provides important references for clinicians and demonstrates the potential application of the proposed algorithm in the diagnosis of pulmonary diseases.
The rapid and accurate extraction of adventitious lung sounds (ALSs) from original lung sounds is greatly significant for diagnosing lung diseases and assessing lung condition. Due to interference from heart sounds and various noises, the empirical mode decomposition (EMD), variational mode decomposition (VMD) and some other classical algorithms have poor performance. Here, an efficient new adaptive variational mode decomposition (AVMD) algorithm is proposed to improve the efficiency for extracting ALSs. For minimizing the bandwidth of each extracted mode and reducing frequency aliasing between modes, the proposed algorithm constructs a frequency-constrained model based on VMD. In order to further improve its performance, the algorithm adopts a strategy of gradually extracting each mode to determine the optimal number of modes for avoiding the under-decomposition or over-decomposition, and uses Pool Adjacent Violators (PAV) to automatically initialize the center frequency of each mode to reduce algorithm iteration steps. Based on the above improved characteristics, the experiments presented in this paper, which conducted on the artificial simulation signal and 102 groups of lung sounds from 20 patients with severe pulmonary diseases, highlight the proposed AVMD's superiority over the other five algorithms when comprehensively considering both decomposition quality and computational efficiency. Furthermore, the above results of 102 groups of lung sounds are statistically analyzed to obtain the characteristic frequency distribution of ALSs, which can provide important references for clinicians and demonstrate the potential application of the proposed algorithm in the diagnosis of pulmonary diseases.
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