Physics-Informed Statistical Learning for spatial and functional data

Spatial Regression with Partial Differential Equation regularization (SR-PDE) is a novel class of models for the analysis of spatially (and space-time) distributed data, that merges advanced statistical methodology and numerical analysis techniques. Thanks to the combination of potentialities from these two scientific areas, the proposed class of models has important advantages with respect to classical spatial data analysis techniques. SR-PDE is able to efficiently deal with data distributed over irregularly shaped domains, with complex boundaries, strong concavities and interior holes [1]. Moreover, it can comply with specific conditions at the boundaries of the problem domain [1, 2, 3], which is fundamental in many applications to obtain meaningful estimates. The proposed models have the capacity to incorporate problem-specific prior information about the spatial structure of the phenomenon under study, formalized in terms of a governing partial differential equation; this very flexible modeling of space-variation allows to naturally account for anisotropy and non-stationarity [2, 3, 10, 11]. Space-varying covariate information is also included in the models via a semiparametric framework. A generalized linear setting allows for response variables having any distribution within the exponential family [8], including also Poisson count data. Quantile regression is also possibile in this modeling framework, along the lines discussed in Density estimation from point-pattern data is described in [19, 20, 21]. Spatial regression with differential regularizations can also deal with data scattered over non-planar domains, specifically over Riemannian manifold domains, including surface domains with non-trivial geometries [4, 5, 6, 7, 13] and non-convex volumes [22, 23]. This has fascinating applications in the earth-sciences, in the life-sciences [4, 5, 6, 13, 22] and in engineering [7]. The models can also be extended to space-time data and spatially dependent functional data [9, 11, 12, 13, 25]. Moreover, building on these regression models, it is possible to define a principal component analysis technique for signals spatially distributed over complex domains [6, 22, 24], thus enabling population studies. The use of advanced numerical analysis techniques, and in particular of the finite element method and of isogeometric analysis [7], makes the models computationally very efficient [24]. Some first results on the consistency of the estimators are given in [18] and on inferential methods for the linear part of the models in [16, 17]. Introductions to this line of reserach are given in [14, 15]. Some computational aspects are discussed in [24]. An R/C++ library implementing these models is released via The Comprehensive R Archive Network [29].

Download code:  

   fdaPDE library in CRAN

   fdaPDE library under development in GitHub

References

1. Sangalli*, L.M., Ramsay, J.O., Ramsay, T.O. (2013),
   Spatial spline regression models,
   Journal of the Royal Statistical Society Ser. B, Statistical Methodology, 75, 4, 681-703.
   PDF     Postprint     Code 
2. Azzimonti#, L., Nobile, F., Sangalli*, L.M., Secchi, P. (2014),
   Mixed Finite Elements for spatial regression with PDE penalization,
   SIAM/ASA Journal on Uncertainty Quantification, Vol. 2, No. 1, pp. 305-335.
   PDF     Postprint     Code
3. Azzimonti#, L., Sangalli*, L.M., Secchi, P., Domanin, M., Nobile, F. (2015),
   Blood flow velocity field estimation via spatial regression with PDE penalization,
   Journal of the American Statistical Association, Theory and Methods, 110 (511), 1057-1071.
   PDF     Postprint     Supplementary material      Code 
4. Dassi, F., Ettinger#, B., Perotto, S., Sangalli, L.M. (2015),
   A mesh simplification strategy for a spatial regression analysis over the cortical surface of the brain,
   Applied Numerical Mathematics, Vol. 90, pp. 111-131.
   PDF     Postprint     Code 
5. Ettinger#, B., Perotto, S., Sangalli*, L.M. (2016),
   Spatial regression models over two-dimensional manifolds,
   Biometrika, 103 (1), 71-88.
   PDF     Postprint     Supplementary material     Code 
6. Lila#, E., Aston, J.A.D., Sangalli, L.M. (2016),
   Smooth Principal Component Analysis over two-dimensional manifolds with an application to Neuroimaging, 
   Annals of Applied Statistics, 10 (4), 1854-1879.
   PDF     PostprintCode 
7. Wilhelm#, M., Dede’, L., Sangalli, L.M., Wilhelm, P. (2016),
   IGS: an IsoGeometric approach for Smoothing on surfaces,
   Computer Methods in Applied Mechanics and Engineering, 302, 70-89. 
   PDF     Postprint
8. Wilhelm#, M., Sangalli*, L.M. (2016),
   Generalized Spatial Regression with Differential Regularization,
   Journal of Statistical Computation and Simulation, 86 (13), 2497-2518.
   PDF     Postprint     Code 
9. Bernardi#, M.S., Sangalli*, L.M., Mazza#, G., Ramsay, J.O. (2017),
   A penalized regression model for spatial functional data with application to the analysis of the production of waste in Venice province,
   Stochastic Environmental Research and Risk Assessment, 31 (1), 23-38.
   PDF     Postprint     Code 
10. Bernardi#, M.S., Carey, M., Ramsay, J.O., and Sangalli*, L.M. (2018),
    Modeling spatial anisotropy via regression with partial differential regularization,
    Journal of Multivariate Analysis, 167, 15-30.
    PDF     Postprint     Code 
11. Arnone#, E., Azzimonti#, A., Nobile, F., and Sangalli*, L.M. (2019),
    Modelling spatially dependent functional data via regression with differential regularization,
    Journal of Multivariate Analysis, 170, 275-295.
    PDF     Postprint     Code 
12. Arnone#, E., Sangalli*, L.M. and Vicini, A. (2022),
    Smoothing spatio-temporal data with complex missing data patterns,
    Statistical Modelling, DOI: 10.1177/1471082X211057959. 
    PDF     Postprint     Code 
13. Ponti#, L., Perotto, S. and Sangalli, L.M. (2022),
    A PDE-regularized smoothing method for space-time data over manifolds with application to medical data,
    International Journal for Numerical Methods in Biomedical Engineering, 38, 12, e3650.  
    PDF     Code 
14. Sangalli*, L.M. (2020),
    A novel approach to the analysis of spatial and functional data over complex domains,
    Quality Engineering, 32, 2, 181-190, 
    followed by discussions and a rejoinder by the author. 
    PDF     Postprint     Code
    Sangalli*, L.M. (2020),
    Rejoinder,
    Quality Engineering, 32, 2, 197-198. 
    PDF
15. Sangalli*, L.M. (2021),
    Spatial regression with partial differential equation regularization,
    International Statistical Review, 89, 3, 505-531. 
    PDF     Code 
16. Arnone#, E., Kneip, A., Nobile, F. and Sangalli*, L.M. (2022),
    Some first results on the consistency of spatial regression with partial differential equation regularization,
    Statistica Sinica, 32, 209-238.
    PDF     Postprint
17. Ferraccioli#, F., Sangalli*, L.M., Finos, L. (2022),
    Some first inferential tools for spatial regression with differential regularization,
    Journal of Multivariate Analysis, DOI: 10.1016/j.jmva.2021.104866. 
    PDF     Postprint
18. Ferraccioli#, F., Sangalli, L.M., Finos, L. (2023),
    Nonparametric tests for semiparametric regression models”,
    TEST, to appear.
19. Ferraccioli#, F., Arnone#, E., Finos, L., Ramsay, J.O., Sangalli*, L.M. (2021),
    Nonparametric density estimation over complicated domains,
    Journal of the Royal Statistical Society Ser. B, Statistical Methodology, 83, 346-368. 
    PDF     Code 
20. Arnone#, E., Ferraccioli#, F., Pigolotti#, C., Sangalli*, L.M. (2022),
    A roughness penalty approach to estimate densities over two-dimensional manifolds,
    Computational Statistics and Data Analysis, 174, 107527. 
    PDF     Postprint     Code
21. Begu#, B., Panzeri#, S., Arnone, E., Carey, M., and Sangalli*, L.M. (2024),
    A nonparametric penalized likelihood approach to density estimation of space-time point patterns,
    Spatial Statistics, DOI: 10.1016/j.spasta.2024.100824.
    PDF     Code
22. Arnone#, E., Negri#, L., Panzica, F. and Sangalli*, L.M. (2023),
    Analyzing data in complicated 3D domains: smoothing, semiparametric regression and functional principal component analysis,
    Biometrics, DOI: 10.1111/biom.13845.
    PDF     Code
23. Clementi#, L., Arnone, E., Santambrogio, M., Franceschetti, S., Panzica, F. and Sangalli*, L.M. (2023),
    Anatomically compliant modes of variations: new tools for brain connectivity,
    Plos One, DOI: 10.1371/journal.pone.0292450.
    PDF     Code
24. Arnone, E., De Falco, C., Formaggia, L., Meretti, G., and Sangalli, L.M. (2023),
    Computationally efficient techniques for spatial regression with differential regularization,
    International Journal of Computer Mathematics, DOI: 10.1080/00207160.2023.2239944.
    PDF     Code
25. Palummo#, A., Arnone, E., Formaggia, L., and Sangalli*, L.M. (2024),
    Functional principal component analysis for incomplete space-time data ,
    Environmental and Ecological Statistics, DOI: doi.org/10.1007/s10651-024-00598-7.
    PDF      Code
26. Castiglione#, C., Arnone, E., Bernardi, M., Farcomeni, A., and Sangalli*, L.M. (2024),
    PDE-regularised spatial quantile regression,
    Journal of Multivariate Analysis, DOI: 10.1016/j.jmva.2024.105381.
    PDF      Code
27. Tomasetto#, M., Arnone, E., and Sangalli*, L.M. (2024),
    Modeling anisotropy and non-stationarity through physics-informed spatial regression ,
    Environmetrics, DOI: 10.1002/env.2889.
    PDF      Code
28. Cavazzutti#, M., Arnone, E., Ferraccioli, F., Galimberti#, C., Finos, L., and Sangalli*, L.M. (2024),
    Sign-flip inference for spatial regression with differential regularisation,
    Stat, 13, 3, DOI: 10.1002/sta4.711.
    PDF      Code
29. Arnone, E., Clemente#, A., Sangalli, L.M., Lila#, E., Ramsay, J., and Formaggia, L. (2023),
    fdaPDE: Physics-Informed Spatial and Functional Data Analysis, R package available from CRAN
    https://cran.r-project.org/package=fdaPDE

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