Detection of Abnormal Activities from Various Signals Based on Statistical Analysis

Low-frequency signals comprise different types such as Electroencephalogram (EEG), gyroscope and seismic signals. Processing of EEG signals is performed for tasks such as seizure prediction and detection. On the other hand, processing of seismic and gyroscope signals is performed for tasks such as a...

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Bibliographic Details
Published inWireless personal communications Vol. 125; no. 2; pp. 1013 - 1046
Main Authors El-Gindy, Saly Abd-Elateif, Ibrahim, Fatma E., Alabasy, Mohamed, Abdelzaher, Hesham M., El-Refy, Mahmoud, Khalaf, Ashraf A. M., El-Dolil, Sami M., El-Fishawy, Adel S., Taha, Taha E., El-Rabaie, El-Sayed M., Dessouky, Moawad I., El-Dokany, Ibrahim, Oraby, Osama A., N. Alotaiby, Turky, Alshebeili, Saleh A., Abd El-Samie, Fathi E.
Format Journal Article
LanguageEnglish
Published New York Springer US 01.07.2022
Springer Nature B.V
Subjects
Anomalies
Communications Engineering
Computer Communication Networks
Decision making
Discrete cosine transform
Electroencephalography
Engineering
Frequency analysis
Gyroscopes
Networks
Seizures
Signal processing
Signal,Image and Speech Processing
Statistical analysis
Training
Wavelet transforms
Seizure prediction
DCT and DST compression
Wavelet families
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Summary:Low-frequency signals comprise different types such as Electroencephalogram (EEG), gyroscope and seismic signals. Processing of EEG signals is performed for tasks such as seizure prediction and detection. On the other hand, processing of seismic and gyroscope signals is performed for tasks such as activity classification. This paper presents two efficient models for anticipation of anomalies from low-frequency signals. A detailed study of EEG seizure prediction is introduced in this paper based on wavelet-domain processing and compression techniques as an example. The first model uses different families of wavelet transform, while the second one concentrates on lossy compression techniques and their effect on further processing for seizure prediction in a realistic signal acquisition and compression scenario. The prediction approach adopts statistical processing with training and testing phases. The training phase comprises estimation of six signal attributes: amplitude, derivative, local mean, local variance, local median and entropy. On the other hand, the testing phase is performed with a thresholding strategy on the selected  probability bins. A majority voting strategy with a moving average smoothing filter is used for decision making. The suggested models are executed on long-term EEG recordings from the available Physio-Net EEG dataset. Simulation results in the first model show that the Daubechies wavelets demonstrate the best prediction results as the filter lengths in these wavelets are longer than those in the Haar wavelet. The obtained results in the second model prove the feasibility of lossy compression, especially Discrete Cosine Transform (DCT) compression for seizure prediction.
ISSN:0929-6212
1572-834X
DOI:10.1007/s11277-022-09565-6