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Applying Multivariate Segmentation Methods to Human Activity Recognition From Wearable Sensors' Data.

Kenan Li1, Rima Habre1, Huiyu Deng1

  • 1Department of Preventive Medicine, Keck School of Medicine of University of Southern California, Los Angeles, CA, United States.

JMIR Mhealth and Uhealth
|February 8, 2019
PubMed
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This summary is machine-generated.

Greedy Gaussian segmentation (GGS) offers improved human activity recognition (HAR) by adapting to variable activity durations. This method provides more stable predictions and higher accuracy than fixed-size windows, aiding personalized medicine and research.

Area of Science:

  • Biomedical engineering
  • Machine learning
  • Wearable technology

Background:

  • Accurate physical activity quantification is crucial for personalized medicine and epidemiological studies, such as managing asthma exacerbations.
  • Existing human activity recognition (HAR) algorithms often use fixed-size windows, which struggle with real-world variable activity durations.
  • Short windows yield noisy data, while long windows miss brief, intense activities.

Purpose of the Study:

  • To develop an HAR framework that accommodates variable activity bout durations.
  • To detect change points in multivariate time series data to define activity bouts.
  • To predict physical activity within these dynamically defined, homogeneous windows.

Main Methods:

  • Applied fixed-width sliding windows and greedy Gaussian segmentation (GGS) to sensor data (accelerometer, gyroscope).
Keywords:
machine learningphysical activitysmartphonestatistical data analysis wearable devices

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  • Utilized Xgboost models for activity prediction within segmented windows.
  • Validated methods on the HARuS (adults, smartphone) and BREATHE (children, smartwatch) datasets, including simulated variable activity durations.
  • Main Results:

    • GGS produced the least noisy predictions in both datasets.
    • GGS achieved high accuracy rates: 91.06% in HARuS and 79.4% in BREATHE.
    • While fixed-size windows showed slightly higher peak accuracy in HARuS, GGS demonstrated superior performance with variable bout durations.

    Conclusions:

    • GGS multivariate segmentation effectively creates adaptive windows for more stable and accurate HAR compared to fixed-size methods.
    • The approach shows promise for real-world applications, though accuracy varies with data collection context (e.g., device, population).
    • GGS, initially offline, is adaptable for real-time HAR prediction using streaming data.