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System for automatic gait analysis based on a single RGB-D camera

Author

Listed:
  • Ana Patrícia Rocha
  • Hugo Miguel Pereira Choupina
  • Maria do Carmo Vilas-Boas
  • José Maria Fernandes
  • João Paulo Silva Cunha

Abstract

Human gait analysis provides valuable information regarding the way of walking of a given subject. Low-cost RGB-D cameras, such as the Microsoft Kinect, are able to estimate the 3-D position of several body joints without requiring the use of markers. This 3-D information can be used to perform objective gait analysis in an affordable, portable, and non-intrusive way. In this contribution, we present a system for fully automatic gait analysis using a single RGB-D camera, namely the second version of the Kinect. Our system does not require any manual intervention (except for starting/stopping the data acquisition), since it firstly recognizes whether the subject is walking or not, and identifies the different gait cycles only when walking is detected. For each gait cycle, it then computes several gait parameters, which can provide useful information in various contexts, such as sports, healthcare, and biometric identification. The activity recognition is performed by a predictive model that distinguishes between three activities (walking, standing and marching), and between two postures of the subject (facing the sensor, and facing away from it). The model was built using a multilayer perceptron algorithm and several measures extracted from 3-D joint data, achieving an overall accuracy and F1 score of 98%. For gait cycle detection, we implemented an algorithm that estimates the instants corresponding to left and right heel strikes, relying on the distance between ankles, and the velocity of left and right ankles. The algorithm achieved errors for heel strike instant and stride duration estimation of 15 ± 25 ms and 1 ± 29 ms (walking towards the sensor), and 12 ± 23 ms and 2 ± 24 ms (walking away from the sensor). Our gait cycle detection solution can be used with any other RGB-D camera that provides the 3-D position of the main body joints.

Suggested Citation

  • Ana Patrícia Rocha & Hugo Miguel Pereira Choupina & Maria do Carmo Vilas-Boas & José Maria Fernandes & João Paulo Silva Cunha, 2018. "System for automatic gait analysis based on a single RGB-D camera," PLOS ONE, Public Library of Science, vol. 13(8), pages 1-24, August.
    • Handle: RePEc:plo:pone00:0201728
    DOI: 10.1371/journal.pone.0201728
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    References listed on IDEAS

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    1. Karatzoglou, Alexandros & Meyer, David & Hornik, Kurt, 2006. "Support Vector Machines in R," Journal of Statistical Software, Foundation for Open Access Statistics, vol. 15(i09).
    2. Karatzoglou, Alexandros & Smola, Alexandros & Hornik, Kurt & Zeileis, Achim, 2004. "kernlab - An S4 Package for Kernel Methods in R," Journal of Statistical Software, Foundation for Open Access Statistics, vol. 11(i09).
    3. Jochen Klucken & Jens Barth & Patrick Kugler & Johannes Schlachetzki & Thore Henze & Franz Marxreiter & Zacharias Kohl & Ralph Steidl & Joachim Hornegger & Bjoern Eskofier & Juergen Winkler, 2013. "Unbiased and Mobile Gait Analysis Detects Motor Impairment in Parkinson's Disease," PLOS ONE, Public Library of Science, vol. 8(2), pages 1-9, February.
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    Cited by:

    1. Liliane Pinho de Almeida & Leandro Caetano Guenka & Danielle de Oliveira Felipe & Renato Porfirio Ishii & Pedro Senna de Campos & Thomaz Nogueira Burke, 2023. "Correlation between MOVA3D, a Monocular Movement Analysis System, and Qualisys Track Manager (QTM) during Lower Limb Movements in Healthy Adults: A Preliminary Study," IJERPH, MDPI, vol. 20(17), pages 1-11, August.

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