Heart rate tracking in photoplethysmography signals affected by motion artifacts: a review

Ismail, Shahid; Akram, Usman; Siddiqi, Imran

doi:10.1186/s13634-020-00714-2

Cited by 58 publications

(42 citation statements)

References 97 publications

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“…Since modern wearable applications demand for these measures, this research concentrates on HR tracking algorithms applied in time domain. Before the pulse feature detection and validation takes place, usually preprocessing and motion artifact removal stages are applied [19], [40].…”

Section: A Methods For Heart Rate Monitoringmentioning

confidence: 99%

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Optimal Preprocessing of Raw Signals from Reflective Mode Photoplethysmography in Wearable Devices

Wolling

Wasala

Laerhoven

2021

2021 43rd Annual International Conference of the IEEE Engineering in Medicine &Amp; Biology Society (EMBC)

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The optical measurement principle photoplethysmography has emerged in today's wearable devices as the standard to monitor the wearer's heart rate in everyday life. This cost-effective and easy-to-integrate technique has transformed from the original transmission mode pulse oximetry for clinical settings to the reflective mode of modern ambulatory, wrist-worn devices. Numerous proposed algorithms aim at the efficient heart rate measurement and accurate detection of the consecutive pulses for the derivation of secondary features from the heart rate variability. Most, however, have been evaluated either on own, closed recordings or on public datasets that often stem from clinical pulse oximeters in transmission instead of wearables' reflective mode. Signals tend furthermore to be preprocessed with filters, which are rarely documented and unintentionally fitted to the available and applied signals.We investigate the influence of preprocessing on the peak positions and present the benchmark of two cutting-edge pulse detection algorithms on actual raw measurements from reflective mode photoplethysmography. Based on 21806 pulse labels, our evaluation shows that the most suitable but still universal filter passband is located at 0.5 to 15.0 Hz since it preserves the required harmonics to shape the peak positions.

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Section: A Methods For Heart Rate Monitoringmentioning

confidence: 99%

“…Consequently, the universal cardiac and respiratory frequency bands, for both infants and adults, overlap. The separation of the desired signal components from in-band noise, especially motion artifacts from daily activities such as walking and jogging (1.0 to 2.5 Hz), becomes even more challenging [18], [40].…”

Section: A Methods For Heart Rate Monitoringmentioning

confidence: 99%

Optimal Preprocessing of Raw Signals from Reflective Mode Photoplethysmography in Wearable Devices

Wolling

Wasala

Laerhoven

2021

2021 43rd Annual International Conference of the IEEE Engineering in Medicine &Amp; Biology Society (EMBC)

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“…Due to the high probability of the proximity of HR and motion artifact spectral peaks and spectral peak randomness, the removal of motion artifacts is an important preprocessing step in classical signal processing to calculate the HR from PPG. In [19], HR calculations were divided into four phases, including pre-filtering, motion artifact removal, peak detection, and peak tracking. Zong [20] addressed the HR tracking problem in two distinct stages: pre-filtering and peak tracking.…”

Section: Sources Of Inaccuracy-motion Artifactsmentioning

confidence: 99%

“…Ismail [19] showed that the Laplacian model exhibited the best fit for analyzing the d process. Based on the analytical results, the probability density function ( ) is given by the following:…”

Section: Laplacian Distributionmentioning

confidence: 99%

An Adaptive Heart Rate Monitoring Algorithm for Wearable Healthcare Devices

Kuo

Teng

et al. 2021

Electronics

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This paper focuses on developing an adaptive heart rate monitoring algorithm for wrist-based rehabilitation systems. Due to the characteristics of the wrist, the heartbeat measurements are unstable. To improve the preprocessing efficiency and perform measurement calibration, a novel joint algorithm incorporating automatic multiscale-based peak detection and fuzzy logic control (AMPD-Fuzzy) is proposed. The monitoring approach consists of two phases: (1) Preprocessing and (2) Detection and Calibration. Phase 1 explores the parameter settings, threshold, and decision rules. Phase 2 applies fuzzy logic control and the Laplacian model to provide signal reshaping. Experimental results show that the proposed algorithm can effectively achieve heart rate monitoring for wearable healthcare devices.

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“…The periodicity of measured light corresponds to the cardiac rhythm, which is used for HR estimation [ 6 ]. However, this method has one major drawback: during intense physical activity, the PPG signal is very susceptible to interference [ 7 ]. Reducing the influence of motion artifacts is currently a leading research direction in HR estimation.…”

Section: Introductionmentioning

confidence: 99%

Multi-Headed Conv-LSTM Network for Heart Rate Estimation during Daily Living Activities

Wilkosz

Szczęsna

2021

Sensors

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Non-invasive photoplethysmography (PPG) technology was developed to track heart rate during physical activity under free-living conditions. Automated analysis of PPG has made it useful in both clinical and non-clinical applications. Because of their generalization capabilities, deep learning methods can be a major direction in the search for a heart rate estimation solution based on signals from wearable devices. A novel multi-headed convolutional neural network model enriched with long short-term memory cells (MH Conv-LSTM DeepPPG) was proposed for the estimation of heart rate based on signals measured by a wrist-worn wearable device, such as PPG and acceleration signals. For the PPG-DaLiA dataset, the proposed solution improves the performance of previously proposed methods. An experimental approach was used to develop the final network architecture. The average mean absolute error (MAE) of the final solution was 6.28 bpm and Pearson’s correlation coefficient between the estimated and true heart rate values was 0.85.

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Heart rate tracking in photoplethysmography signals affected by motion artifacts: a review

Cited by 58 publications

References 97 publications

Optimal Preprocessing of Raw Signals from Reflective Mode Photoplethysmography in Wearable Devices

Optimal Preprocessing of Raw Signals from Reflective Mode Photoplethysmography in Wearable Devices

An Adaptive Heart Rate Monitoring Algorithm for Wearable Healthcare Devices

Multi-Headed Conv-LSTM Network for Heart Rate Estimation during Daily Living Activities

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