Detecting free-living steps and walking bouts: validating an algorithm for macro gait analysis

Hickey, Aodhán, Del Din, Silvia, Rochester, Lynn and Godfrey, Alan (2017) Detecting free-living steps and walking bouts: validating an algorithm for macro gait analysis. Physiological Measurement, 38 (1). N1-N15. ISSN 0967-3334

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Official URL: https://doi.org/10.1088/1361-6579/38/1/N1

Abstract

Research suggests wearables and not instrumented walkways are better suited to quantify gait outcomes in clinic and free-living environments, providing a more comprehensive overview of walking due to continuous monitoring. Numerous validation studies in controlled settings exist, but few have examined the validity of wearables and associated algorithms for identifying and quantifying step counts and walking bouts in uncontrolled (free-living) environments. Studies which have examined free-living step and bout count validity found limited agreement due to variations in walking speed, changing terrain or task. Here we present a gait segmentation algorithm to define free-living step count and walking bouts from an open-source, high-resolution, accelerometer-based wearable (AX3, Axivity). Ten healthy participants (20–33 years) wore two portable gait measurement systems; a wearable accelerometer on the lower-back and a wearable body-mounted camera (GoPro HERO) on the chest, for 1 h on two separate occasions (24 h apart) during free-living activities. Step count and walking bouts were derived for both measurement systems and compared. For all participants during a total of almost 20 h of uncontrolled and unscripted free-living activity data, excellent relative (rho  ≥  0.941) and absolute (ICC(2,1)  ≥  0.975) agreement with no presence of bias were identified for step count compared to the camera (gold standard reference). Walking bout identification showed excellent relative (rho  ≥  0.909) and absolute agreement (ICC(2,1)  ≥  0.941) but demonstrated significant bias. The algorithm employed for identifying and quantifying steps and bouts from a single wearable accelerometer worn on the lower-back has been demonstrated to be valid and could be used for pragmatic gait analysis in prolonged uncontrolled free-living environments.

Item Type: Article
Subjects: B900 Others in Subjects allied to Medicine
G900 Others in Mathematical and Computing Sciences
Department: Faculties > Engineering and Environment > Computer and Information Sciences
Depositing User: Becky Skoyles
Date Deposited: 20 Apr 2018 11:56
Last Modified: 01 Aug 2021 08:47
URI: http://nrl.northumbria.ac.uk/id/eprint/34045

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