Fusion of Heart Rate, Respiration and Motion Measurements from a Wearable Sensor System to Enhance Energy Expenditure Estimation

Lu, Ke; Yang, Liyun; Seoane, Fernando; Abtahi, Farhad; Forsman, Mikael; Lindecrantz, Kaj

doi:10.3390/s18093092

Cited by 35 publications

(22 citation statements)

References 48 publications

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“…Similar findings were shown by Mackintosh et al (2016), who found that two-accelerometer systems had superior accuracy to systems of 3-8 accelerometers when assessing energy expenditure in children. As an alternate to using more accelerometers, using additional sensors alongside an accelerometer (within a single monitor or as a multi-monitor system), such as heart rate or gyroscope, has been shown to improve measurement of energy expenditure and may be considered as an option for further improvement of physical activity intensity assessment (O'Driscoll et al, 2018;Lu et al, 2018;Hibbing et al, 2018).…”

Section: Comparisons Across Demographic Variables For Boosting Methodmentioning

confidence: 99%

Statistical Learning Methods to Predict Activity Intensity from Body-Worn Accelerometers

Lazar

Begum²,

Murshed³

et al. 2020

J. biomed. anal.

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Physical activity, especially when performed at moderate or vigorous intensity, has short- and long-term health benefits, but measurement of free-living physical activity is challenging. Accelerometers are popular tools to assess physical activity, although accuracy of conventional accelerometer analysis methods is suboptimal. This study developed and tested statistical learning models for assessing activity intensity from body-worn accelerometers. Twenty-eight adults performed 10-21 activities of daily living in two visits while wearing four accelerometers (right hip, right ankle, both wrists). Accelerometer placement is of crucial practical concern and this paper addresses this issue. Boosting, bagging, random forest and decision tree models were created for each accelerometer and for two-, three-, and four-accelerometer combinations to predict activity intensity. Research staff observations of activity intensity served as the criterion. Point estimates of error for the ankle accelerometer were 2.2-4.7 percentage points lower than other single-accelerometer placements, and the left wrist-ankle combination had errors 0.8-5.8 percentage points lower than other two-accelerometer combinations. Decision trees had poorer accuracy than the other models. Using an accelerometer worn on the lower limb, by itself or in combination with an upper-limb accelerometer, appears to offer optimal accuracy for activity intensity measurement.

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Section: Comparisons Across Demographic Variables For Boosting Methodmentioning

confidence: 99%

Statistical Learning Methods to Predict Activity Intensity from Body-Worn Accelerometers

Lazar

Begum²,

Murshed³

et al. 2020

J. biomed. anal.

View full text Add to dashboard Cite

show abstract

“…TIP has been used to measure lung volume changes [255], to evaluate respiratory condition during normal and deep breathing [256], the assessment of asthma risk from tidal flow variability [257], sleep disorders [258], energy expenditure estimation [259], or even the detection of body posture changes [260]. Another application of TIP is the gating of positron-emission tomography (PET) and singlephoton emission computed tomography (SPECT) images.…”

Section: Transthoracic Impedance Pneumographymentioning

confidence: 99%

Fundamentals, Recent Advances, and Future Challenges in Bioimpedance Devices for Healthcare Applications

2019

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This work develops a thorough review of bioimpedance systems for healthcare applications. The basis and fundamentals of bioimpedance measurements are described covering issues ranging from the hardware diagrams to the configurations and designs of the electrodes and from the mathematical models that describe the frequency behavior of the bioimpedance to the sources of noise and artifacts. Bioimpedance applications such as body composition assessment, impedance cardiography (ICG), transthoracic impedance pneumography, electrical impedance tomography (EIT), and skin conductance are described and analyzed. A breakdown of recent advances and future challenges of bioimpedance is also performed, addressing topics such as transducers for biosensors and Lab-on-Chip technology, measurements in implantable systems, characterization of new parameters and substances, and novel bioimpedance applications.

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“…The promising results provided by this method showed its capability in characterizing high-dimensional time series patterns and providing useful information with wearable sensors in table tennis coaching. Lu et al [15] developed and tested a new method that combined information from heart rate, respiration, and accelerations measurements to estimate energy expenditure. These data measurements were taken from wearable sensor system and were integrated by neural network based model.…”

Section: Summary Of Special Issue Papersmentioning

confidence: 99%

Data Analytics and Applications of the Wearable Sensors in Healthcare: An Overview

Uddin

Syed-Abdul

2020

Sensors

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Fusion of Heart Rate, Respiration and Motion Measurements from a Wearable Sensor System to Enhance Energy Expenditure Estimation

Cited by 35 publications

References 48 publications

Statistical Learning Methods to Predict Activity Intensity from Body-Worn Accelerometers

Statistical Learning Methods to Predict Activity Intensity from Body-Worn Accelerometers

Fundamentals, Recent Advances, and Future Challenges in Bioimpedance Devices for Healthcare Applications

Data Analytics and Applications of the Wearable Sensors in Healthcare: An Overview

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