TY - JOUR
T1 - Dynamic model-based clustering for spatio-temporal data
AU - Paci, Lucia
AU - Finazzi, Francesco
PY - 2018
Y1 - 2018
N2 - In many research fields, scientific questions are investigated by analyzing data collected over space and time, usually at fixed spatial locations and time steps and resulting in geo-referenced time series. In this context, it is of interest to identify potential partitions of the space and study their evolution over time. A finite space-time mixture model is proposed to identify level-based clusters in spatio-temporal data and study their temporal evolution along the time frame. We anticipate space-time dependence by introducing spatio-temporally varying mixing weights to allocate observations at nearby locations and consecutive time points with similar cluster’s membership probabilities. As a result, a clustering varying over time and space is accomplished. Conditionally on the cluster’s membership, a state-space model is deployed to describe the temporal evolution of the sites belonging to each group. Fully posterior inference is provided under a Bayesian framework through Monte Carlo Markov chain algorithms. Also, a strategy to select the suitable number of clusters based upon the posterior temporal patterns of the clusters is offered. We evaluate our approach through simulation experiments, and we illustrate using air quality data collected across Europe from 2001 to 2012, showing the benefit of borrowing strength of information across space and time.
AB - In many research fields, scientific questions are investigated by analyzing data collected over space and time, usually at fixed spatial locations and time steps and resulting in geo-referenced time series. In this context, it is of interest to identify potential partitions of the space and study their evolution over time. A finite space-time mixture model is proposed to identify level-based clusters in spatio-temporal data and study their temporal evolution along the time frame. We anticipate space-time dependence by introducing spatio-temporally varying mixing weights to allocate observations at nearby locations and consecutive time points with similar cluster’s membership probabilities. As a result, a clustering varying over time and space is accomplished. Conditionally on the cluster’s membership, a state-space model is deployed to describe the temporal evolution of the sites belonging to each group. Fully posterior inference is provided under a Bayesian framework through Monte Carlo Markov chain algorithms. Also, a strategy to select the suitable number of clusters based upon the posterior temporal patterns of the clusters is offered. We evaluate our approach through simulation experiments, and we illustrate using air quality data collected across Europe from 2001 to 2012, showing the benefit of borrowing strength of information across space and time.
KW - Bayesian analysis
KW - Computational Theory and Mathematics
KW - Finite mixture models
KW - Markov chain Monte Carlo
KW - State-space modeling
KW - Statistics and Probability
KW - Statistics, Probability and Uncertainty
KW - Theoretical Computer Science
KW - Bayesian analysis
KW - Computational Theory and Mathematics
KW - Finite mixture models
KW - Markov chain Monte Carlo
KW - State-space modeling
KW - Statistics and Probability
KW - Statistics, Probability and Uncertainty
KW - Theoretical Computer Science
UR - http://hdl.handle.net/10807/98610
UR - http://www.kluweronline.com/issn/0960-3174
U2 - 10.1007/s11222-017-9735-9
DO - 10.1007/s11222-017-9735-9
M3 - Article
SN - 0960-3174
VL - 28
SP - 359
EP - 374
JO - Statistics and Computing
JF - Statistics and Computing
ER -