Abstract
Markov models are natural tools for modeling trajectories, following
the principle that recent location history is predictive of
near-future directions. In this work we study Markov models
for describing and predicting human movement in indoor spaces, with
the goal of modeling the movement on a coarse scale to protect the
privacy of the individuals. Modern positioning devices, however,
provide location information on a much more finer scale.
To utilize this additional information we develop a novel
family of partially hidden Markov models that couple each observed
state with an auxiliary side information vector characterizing the
movement within the coarse grid cell. We implement the
model as a non-parametric Bayesian model and demonstrate it on
real-world trajectory data collected in a hypermarket.
the principle that recent location history is predictive of
near-future directions. In this work we study Markov models
for describing and predicting human movement in indoor spaces, with
the goal of modeling the movement on a coarse scale to protect the
privacy of the individuals. Modern positioning devices, however,
provide location information on a much more finer scale.
To utilize this additional information we develop a novel
family of partially hidden Markov models that couple each observed
state with an auxiliary side information vector characterizing the
movement within the coarse grid cell. We implement the
model as a non-parametric Bayesian model and demonstrate it on
real-world trajectory data collected in a hypermarket.
Original language | English |
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Journal | Neurocomputing |
Volume | 266 |
Pages (from-to) | 196-205 |
Number of pages | 10 |
ISSN | 0925-2312 |
DOIs | |
Publication status | Published - 29 Nov 2017 |
MoE publication type | A1 Journal article-refereed |
Fields of Science
- 112 Statistics and probability
- Hierarchical Dirichlet process
- Markov models
- Movement trajectories
- Nonparametric Bayesian inference