Abstract
Gait behaviour is a key health metric. Temporal, spatial and kinetic walking gait parameters are valuable in enhancing sport performance and early health diagnostics. Full gait assessment requires a gait clinic and existing wearable gait tracking systems typically measure isolated subsets of parameters tailored to specific applications. This is useful when the condition to be monitored is known, but fails to offer a comprehensive view of an individual’s gait traits when their pathology is unknown or changing, or a general assessment is required. To support holistic walking gait tracking, we introduce WalkEar, a novel sensing
platform designed to simultaneously track gait parameters using commodity earbuds. WalkEar operates by detecting gait events to derive temporal gait parameters and segment the IMU data.
WalkEar then progresses earable gait assessment by, for the first time, estimating kinetic gait parameters and reconstructing the vGRF curve using machine learning. Each parameter is calculated on a step-to-step basis for gait variability and asymmetry. We developed an earbud prototype and collected data from 13 participants using gold standard force plates and instrumented
treadmill ground truth. Extensive experiments demonstrate the promising performance of WalkEar, achieving an overall MAPE of 5.1% in estimating gait, 2.0% MAPE on kinetic gait parameters, and an NRMSE of 5.3% for vGRF curve reconstruction.
platform designed to simultaneously track gait parameters using commodity earbuds. WalkEar operates by detecting gait events to derive temporal gait parameters and segment the IMU data.
WalkEar then progresses earable gait assessment by, for the first time, estimating kinetic gait parameters and reconstructing the vGRF curve using machine learning. Each parameter is calculated on a step-to-step basis for gait variability and asymmetry. We developed an earbud prototype and collected data from 13 participants using gold standard force plates and instrumented
treadmill ground truth. Extensive experiments demonstrate the promising performance of WalkEar, achieving an overall MAPE of 5.1% in estimating gait, 2.0% MAPE on kinetic gait parameters, and an NRMSE of 5.3% for vGRF curve reconstruction.
| Original language | English |
|---|---|
| Title of host publication | Proceedings of the 2025 IEEE International Conference on Pervasive Computing and Communications |
| Subtitle of host publication | PerCom |
| Publisher | IEEE |
| Number of pages | 11 |
| Publication status | E-pub ahead of print - 21 Mar 2025 |
| Event | 2025 IEEE international Conference on Pervasive Computing and Communications: PerCom - Washington, DC, USA United States Duration: 17 Mar 2025 → 21 Mar 2025 https://www.percom.org/accepted-papers-main-conference/ |
Publication series
| Name | IEEE International Conference on Pervasive Computing and Communications (PerCom) |
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Workshop
| Workshop | 2025 IEEE international Conference on Pervasive Computing and Communications |
|---|---|
| Abbreviated title | PerCom 2025 |
| Country/Territory | USA United States |
| Period | 17/03/25 → 21/03/25 |
| Internet address |
Funding
This work is supported by ERC through Project 833296 (EAR), EPSRC grants EP/Y035925/1, and EP/S023046/1, and Atos.
| Funders | Funder number |
|---|---|
| Engineering and Physical Sciences Research Council | EP/Y035925/1, EP/S023046/1 |
Keywords
- Wearables
- Earables
- Gait
- Spatiotemporal gait parameters
- Kinetic gait parameters
- Ground reaction force
