A Low-Complexity ECG Feature Extraction Algorithm for Mobile Healthcare Applications

Mazomenos, Evangelos B.; Biswas, Dwaipayan; Acharyya, Amit; Chen, Taihai; Maharatna, Koushik; Rosengarten, James A.; Morgan, John M.; Curzen, Nick

doi:10.1109/titb.2012.2231312

Cited by 154 publications

(88 citation statements)

References 31 publications

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“…As shown in next section, approximately 90% of the computation time is devoted to FIR (50%) and morphological (40%) filtering. These two parts are the most computationally intensive and their number of operations gives roughly the complexity of the algorithm [40], since the delineation of the ECG points mainly requires comparisons and means the 10% of the computation time.…”

Section: Estimated Number Of Arithmetic Operationsmentioning

confidence: 99%

A Modular Low-Complexity ECG Delineation Algorithm for Real-Time Embedded Systems

Bote

Recas

Rincon³

et al. 2018

IEEE J. Biomed. Health Inform.

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Abstract-This work presents a new modular and lowcomplexity algorithm for the delineation of the different ECG waves (QRS, P and T peaks, onsets and end). Involving a reduced number of operations per second and having a small memory footprint, this algorithm is intended to perform realtime delineation on resource-constrained embedded systems. The modular design allows the algorithm to automatically adjust the delineation quality in run time to a wide range of modes and sampling rates, from a Ultra-low power mode when no arrhythmia is detected, in which the ECG is sampled at low frequency, to a complete High-accuracy delineation mode in which the ECG is sampled at high frequency and all the ECG fiducial points are detected, in case of arrhythmia. The delineation algorithm has been adjusted using the QT database, providing very high sensitivity and positive predictivity, and validated with the MIT database. The errors in the delineation of all the fiducial points are below the tolerances given by the Common Standards for Electrocardiography (CSE) committee in the High-accuracy mode, except for the P wave onset, for which the algorithm is above the agreed tolerances by only a fraction of the sample duration. The computational load for the ultra-low-power 8-MHz TI MSP430 series microcontroller ranges from 0.2 to 8.5% according to the mode used.

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Section: Estimated Number Of Arithmetic Operationsmentioning

confidence: 99%

A Modular Low-Complexity ECG Delineation Algorithm for Real-Time Embedded Systems

Bote

Recas

Rincon³

et al. 2018

IEEE J. Biomed. Health Inform.

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show abstract

“…Several algorithms achieve beat detection rates greater than 99.5% (Afonso et al, 1999;Adnane et al, 2009). Recent technical advances have made possible to achieve low execution times (even real-time) or to eliminate the need for specific hardware (Quero et al, 2005;Mazomenos et al, 2013). Most of these proposals are based on single-channel detection, in some cases applied independently to two channels of the ECG.…”

Section: Introductionmentioning

confidence: 99%

Detection of Heart Beat Positions in ECG Recordings: A Lead-Dependent Algorithm

Mondelo

Lado

Méndez

et al. 2017

Journal of Information Systems Engineering & Management

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This paper proposes a computerized heartbeat detection method in single-channel electrocardiograms (ECGs). First, the well-known Pan-Tompkins technique was implemented, and next, a channel-dependent version was developed, by adjusting threshold values and reducing false QRS detections. The algorithms were tested with the MIT-BIH Arrhythmia Database (original algorithm), and with the St. Petersburg Database (modified version). When validating the performances of the original Pan-Tompkins algorithm, we have achieved a sensitivity of Se = 99.81, at a positive predictivity (P + ) = 99.85%. The F-Score was 0.9587, and the RMS RR Interval Error (RMSRRIE) resulted to be 4,480.46 ms. When analysing the performance of the modified algorithm, results provided an average value of Se = 99.92%, P + = 99.98%, FScore = 0.9718, and a mean value of 111.05 ms. for the RMSRRIE. In conclusion, the improved PanTompkins algorithm provides higher values for sensitivity and positive predictivity, increased F-Score, and it significantly reduces the temporal error when estimating the positions of QRS complexes. Thus, it could be used as a starting point to detect heartbeat positions in more sophisticated computerized detection systems.

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“…The State-of-the Art techniques may enable to extract the P and T waves correctly in following diseases (sinus arrhythmia, atrioventricular conduction variation and many more) [4], [10] where more likely P and T waves still be detected even though these are absent in the real life signals for the following diseases (Ventricular Arrhythmias, Atrial fibrillation and flutter) resulting in wrong diagnosis and therapy followed. Whereas the proposed methodology will detect the abnormal variation in the intervals and produce the corresponding contour and shows the disparity in the box count.…”

Section: Introductionmentioning

confidence: 99%

“…As shown in Fig.1, ECG samples are initially stored in the memory, for the analysis of stored healthy ECG and unhealthy ECG signals, the boundaries are extracted using our proposed Boundary Detection (BD) methodology [7] and the output of BD is applied to FE block [4] to get the following features QRS complex and PR interval of each and every individual beat. The proposed localized feature analysis methodology takes the features from FE block and plot the PSR of all the intervals and calculate the box count.…”

mentioning

confidence: 99%

Classification Methodology of CVD with Localized Features Analysis Using Phase Space Reconstruction Targeting Personalized Remote Health Monitoring

Vemishetty¹,

Acharyya²,

Das³

et al. 2016

2016 Computing in Cardiology Conference (CinC)

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A Low-Complexity ECG Feature Extraction Algorithm for Mobile Healthcare Applications

Cited by 154 publications

References 31 publications

A Modular Low-Complexity ECG Delineation Algorithm for Real-Time Embedded Systems

A Modular Low-Complexity ECG Delineation Algorithm for Real-Time Embedded Systems

Detection of Heart Beat Positions in ECG Recordings: A Lead-Dependent Algorithm

Classification Methodology of CVD with Localized Features Analysis Using Phase Space Reconstruction Targeting Personalized Remote Health Monitoring

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