AI Article Synopsis
- Barometric altimeters struggle with accurate height tracking due to poor resolution and drifting issues, leading to ongoing debate about their effectiveness for human motion tracking.
- To improve short-term height tracking, a stochastic model is developed to analyze the barometric noise, breaking it down into three components: a changing mean based on global conditions, a Gauss-Markov process for local changes, and an uncorrelated random process from electronic noise.
- Autoregressive-moving average (ARMA) techniques are employed to identify the correlation within the GM component, and moving average filters are tested in dynamic motion scenarios to enhance the tracking of subtle height changes.
Article Abstract
The question whether barometric altimeters can be applied to accurately track human motions is still debated, since their measurement performance are rather poor due to either coarse resolution or drifting behavior problems. As a step toward accurate short-time tracking of changes in height (up to few minutes), we develop a stochastic model that attempts to capture some statistical properties of the barometric altimeter noise. The barometric altimeter noise is decomposed in three components with different physical origin and properties: a deterministic time-varying mean, mainly correlated with global environment changes, and a first-order Gauss-Markov (GM) random process, mainly accounting for short-term, local environment changes, the effects of which are prominent, respectively, for long-time and short-time motion tracking; an uncorrelated random process, mainly due to wideband electronic noise, including quantization noise. Autoregressive-moving average (ARMA) system identification techniques are used to capture the correlation structure of the piecewise stationary GM component, and to estimate its standard deviation, together with the standard deviation of the uncorrelated component. M-point moving average filters used alone or in combination with whitening filters learnt from ARMA model parameters are further tested in few dynamic motion experiments and discussed for their capability of short-time tracking small-amplitude, low-frequency motions.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3871085 | PMC |
| http://dx.doi.org/10.3390/s131115692 | DOI Listing |
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