New algorithms for processing time-series big EEG data within mobile health monitoring systems

•We developed three novel algorithms to process and analyze real time series EEG.•Data transformation relies on compression to reduce transfer time and size of data and increase the network transfer rate.•Data storage and parallel processing is efficiently handled thanks to MapReduce platform.•Inter...

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Bibliographic Details
Published in:Computer methods and programs in biomedicine 2017-10, Vol.149, p.79-94
Main Authors: Serhani, Mohamed Adel, Menshawy, Mohamed El, Benharref, Abdelghani, Harous, Saad, Navaz, Alramzana Nujum
Format: Article
Language:English
Subjects:
Algorithms
Automatic Data Processing
Big data
Data Compression
EEG
Electroencephalography
Epileptic seizure
Humans
Information Storage and Retrieval
Mapreduce
Mobile monitoring
Prospective Studies
Telemedicine
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Summary:•We developed three novel algorithms to process and analyze real time series EEG.•Data transformation relies on compression to reduce transfer time and size of data and increase the network transfer rate.•Data storage and parallel processing is efficiently handled thanks to MapReduce platform.•Interactive mobile visualization allows better identification and analysis of epileptic seizures.•Its applicability is experimentally proven while monitoring epileptic diseases. Recent advances in miniature biomedical sensors, mobile smartphones, wireless communications, and distributed computing technologies provide promising techniques for developing mobile health systems. Such systems are capable of monitoring epileptic seizures reliably, which are classified as chronic diseases. Three challenging issues raised in this context with regard to the transformation, compression, storage, and visualization of big data, which results from a continuous recording of epileptic seizures using mobile devices. In this paper, we address the above challenges by developing three new algorithms to process and analyze big electroencephalography data in a rigorous and efficient manner. The first algorithm is responsible for transforming the standard European Data Format (EDF) into the standard JavaScript Object Notation (JSON) and compressing the transformed JSON data to decrease the size and time through the transfer process and to increase the network transfer rate. The second algorithm focuses on collecting and storing the compressed files generated by the transformation and compression algorithm. The collection process is performed with respect to the on-the-fly technique after decompressing files. The third algorithm provides relevant real-time interaction with signal data by prospective users. It particularly features the following capabilities: visualization of single or multiple signal channels on a smartphone device and query data segments. We tested and evaluated the effectiveness of our approach through a software architecture model implementing a mobile health system to monitor epileptic seizures. The experimental findings from 45 experiments are promising and efficiently satisfy the approach's objectives in a price of linearity. Moreover, the size of compressed JSON files and transfer times are reduced by 10% and 20%, respectively, while the average total time is remarkably reduced by 67% through all performed experiments. Our approach successfully develops efficient al
ISSN:0169-2607
1872-7565
DOI:10.1016/j.cmpb.2017.07.007