This project developed analysis methods for spatio-temporal networks and data, and the temporal evolution of interrelationships. The generation of a network process requires modelling complex interrelationships across time. This is challenging because static networks are just being understood from a formal mathematical point-of-view. The advantage of observing multiple networks is that you have more data, and so know more. Analysis of spatio-temporal networks is challenging due to the combinatorial nature of networks that needs to be combined with a spatio-temporal model for the network structure.
The understanding of time-varying networks is important to society because they are all around us: social networks that influence the political discourse, networks of species that need to be understood in the context of climate change, as well as brain networks that can give insights into the health of individuals.
The objectives of the projects were:
* To build models for temporally-varying interactions, and develop their methods of inference (WP 1 & 2). Achieved results are published in Suveges and Olhede (2023), Lunagomez et al (2022), Chandna et al (2022), Maugis et al (2020).
* To build better models of events (WP 3) and better methods for their analysis; this has been implemented in Rajala et al (2018), Rajala et al (2023), as well as Martin et al (2023).
* To build improved multivariate spatial models and design methods of their estimation (WP 4); this has been implemented in Guillaumin et al (2022).
* To adapt the developed methods to impact problems in ecology and neuroscience (all WPs); results published in Chang et al (2016), Rajala et al (2019), Rupawala et al (2023).
Publications:
S. Chandna et al, Local linear graphon estimation using covariates, Biometrika, 109(3), 721-734, 2022.
P. Chang et al, The development of nociceptive network activity in the somatosensory cortex of freely moving rat pups, Cerebral Cortex, 26(12), 4513-4523, 2016.
A. P. Guillaumin et al, The Debiased Spatial Whittle Likelihood, J. Roy. Stat Soc. B, 84(4), 1526-1557, 2022.
S. Lunagomez et al, Modeling Network populations via graph distances, J. Am. Stat Assoc., 116(536), 2023-2040, 2021.
J. S. Martin et al, Multivariate geometric anisotropic Cox processes, Scand. J. of Stat., 2023.
P. A. Maugis et al, Testing for equivalence of network distribution using subgraph count. J. CGS, 29(3), 455-465, 2020.
T. Rajala et al, When do we have the power to detect biological interactions in spatial point patterns? J. of Ecology, 107(2), 711-721, 2019.
T. Rajala et al, Detecting multivariate interactions in spatial point patterns with Gibbs models and variable selection, J. Roy. Stat. Soc. C, 67(5), 1237-1273, 2018.
T. Rajala et al, What is the Fourier Transform of a Spatial Point Pattern?, IEEE Trans. Info. Theory, 2023.
M. Rupawala et al. A developmental shift in habituation to pain in human neonates, Current Biology, 33(8), 1397-1406, 2023.
M. Suveges and S. C. Olhede, Networks with correlated edge processes, J. Roy. Stat. Soc. A, 2023.
A. Sykulski et al, The debiased Whittle likelihood, Biometrika, 106(2), 251-266, 2019.