References
- Banerjee, S., Gelfand, A. E., Finley, A. O., and Sang, H. (2008), “Gaussian Predictive Process Models for Large Spatial Data Sets,” Journal of the Royal Statistical Society, Series B, 70, 825–848.
- Bevilacqua, M., Gaetan, C., Mateu, J., and Porcu, E. (2012), “Estimating Space and Space-Time Covariance Functions for Large Data Sets: A Weighted Composite Likelihood Approach,” Journal of the American Statistical Association, 107, 268–280.
- Calder, C. A. (2007), “Dynamic Factor Process Convolution Models for Multivariate Space-Time Data With Application to Air Quality Assessment,” Environmental and Ecological Statistics, 14, 229–247.
- Caragea, P. C., and Smith, R. L. (2007), “Asymptotic Properties of Computationally Efficient Alternative Estimators for a Class of Multivariate Normal Models,” Journal of Multivariate Analysis, 98, 1417–1440.
- Chui, C. (1992), An Introduction to Wavelets, San Diego, CA: Academic Press.
- Cressie, N., and Johannesson, G. (2008), “Fixed Rank Kriging for Very Large Spatial Data Sets,” Journal of the Royal Statistical Society, Series B, 70, 209–226.
- Cressie, N., and Wikle, C. K. (2011), Statistics for Spatio-Temporal Data, Hoboken, NJ: Wiley.
- Curriero, F., and Lele, S. (1999), “A Composite Likelihood Approach to Semivariogram Estimation,” Journal of Agricultural, Biological, and Environmental Statistics, 4, 9–28.
- Eidsvik, J., Shaby, B. A., Reich, B. J., Wheeler, M., and Niemi, J. (2014), “Estimation and Prediction in Spatial Models With Block Composite Likelihoods Using Parallel Computing,” Journal of Computational and Graphical Statistics, 23, 295–315.
- Evensen, G. (1994), “Sequential Data Assimilation With a Nonlinear Quasi-Geostrophic Model Using Monte Carlo Methods to Forecast Error Statistics,” Journal of Geophysical Research, 99, 10143–10162.
- Forsythe, J. M., Dodson, J. B., Partain, P. T., Kidder, S. Q., and Haar, T. H. V. (2012), “How Total Precipitable Water Vapor Anomalies Relate to Cloud Vertical Structure,” Journal of Hydrometeorology, 13, 709–721.
- Fuentes, M. (2007), “Approximate Likelihood for Large Irregularly Spaced Spatial Data,” Journal of the American Statistical Association, 102, 321–331.
- Furrer, R., Genton, M. G., and Nychka, D. W. (2006), “Covariance Tapering for Interpolation of Large Spatial Datasets,” Journal of Computational and Graphical Statistics, 15, 502–523.
- Gneiting, T., and Katzfuss, M. (2014), “Probabilistic Forecasting,” Annual Review of Statistics and Its Application, 1, 125–151.
- Golub, G. H., and Van Loan, C. F. (2012), Matrix Computations (4th ed.), Baltimore, MD: JHU Press.
- Gramacy, R., and Lee, H. (2008), “Bayesian Treed Gaussian Process Models With an Application to Computer Modeling,” Journal of the American Statistical Association, 103, 1119–1130.
- Halko, N., Martinsson, P., and Tropp, J. (2011), “Finding Structure With Randomness: Probabilistic Algorithms for Constructing Approximate Matrix Decompositions,” SIAM Review, 53, 217–288.
- Harville, D. A. (1997), Matrix Algebra From a Statistician's Perspective, New York: Springer.
- Henderson, H., and Searle, S. (1981), “On Deriving the Inverse of a Sum of Matrices,” SIAM Review, 23, 53–60.
- Higdon, D. (1998), “A Process-Convolution Approach to Modelling Temperatures in the North Atlantic Ocean,” Environmental and Ecological Statistics, 5, 173–190.
- Hoeting, J. A., Madigan, D., Raftery, A. E., and Volinsky, C. T. (1999), “Bayesian Model Averaging: A Tutorial,” Statistical Science, 14, 382–417.
- Johannesson, G., Cressie, N., and Huang, H.-C. (2007), “Dynamic Multi-Resolution Spatial Models,” Environmental and Ecological Statistics, 14, 5–25.
- Katzfuss, M. (2013), “Bayesian Nonstationary Spatial Modeling for Very Large Datasets,” Environmetrics, 24, 189–200.
- Katzfuss, M., and Cressie, N. (2009), “Maximum Likelihood Estimation of Covariance Parameters in the Spatial-Random-Effects Model,” in Proceedings of the Joint Statistical Meetings, Alexandria, VA: American Statistical Association, pp. 3378–3390.
- ——— (2011), “Spatio-Temporal Smoothing and EM Estimation for Massive Remote-Sensing Data Sets,” Journal of Time Series Analysis, 32, 430–446.
- ——— (2012), “Bayesian Hierarchical Spatio-Temporal Smoothing for Very Large Datasets,” Environmetrics, 23, 94–107.
- Katzfuss, M., and Hammerling, D. (2017), “Parallel Inference for Massive Distributed Spatial Data Using Low-Rank Models,” Statistics and Computing, 27, 363--375.
- Katzfuss, M., Stroud, J. R., and Wikle, C. K. (2016), “Understanding the Ensemble Kalman Filter,” The American Statistician, 70, 350–357.
- Kaufman, C. G., Schervish, M., and Nychka, D. W. (2008), “Covariance Tapering for Likelihood-Based Estimation in Large Spatial Data Sets,” Journal of the American Statistical Association, 103, 1545–1555.
- Kidder, S. Q., and Jones, A. S. (2007), “A Blended Satellite Total Precipitable Water Product for Operational Forecasting,” Journal of Atmospheric and Oceanic Technology, 24, 74–81.
- Lemos, R. T., and Sansó, B. (2009), “A Spatio-Temporal Model for Mean, Anomaly, and Trend Fields of North Atlantic Sea Surface Temperature,” Journal of the American Statistical Association, 104, 5–18.
- Lindgren, F., Rue, H., and Lindström, J. (2011), “An Explicit Link Between Gaussian Fields and Gaussian Markov Random Fields: The Stochastic Partial Differential Equation Approach,” Journal of the Royal Statistical Society, Series B, 73, 423–498.
- Mardia, K., Goodall, C., Redfern, E., and Alonso, F. (1998), “The Kriged Kalman Filter,” Test, 7, 217–282.
- McLeod, A. I., Yu, H., and Krougly, Z. (2007), “Algorithms for Linear Time Series Analysis: With R Package,” Journal of Statistical Software, 23, 5.
- Nychka, D. W., Bandyopadhyay, S., Hammerling, D., Lindgren, F., and Sain, S. R. (2016), “A Multi-Resolution Gaussian Process Model for the Analysis of Large Spatial Datasets,” Journal of Computational and Graphical Statistics, 24, 579–599.
- Quiñonero Candela, J., and Rasmussen, C. (2005), “A Unifying View of Sparse Approximate Gaussian Process Regression,” Journal of Machine Learning Research, 6, 1939–1959.
- Sang, H., and Huang, J. Z. (2012), “A Full Scale Approximation of Covariance Functions,” Journal of the Royal Statistical Society, Series B, 74, 111–132.
- Sang, H., Jun, M., and Huang, J. Z. (2011), “Covariance Approximation for Large Multivariate Spatial Datasets With an Application to Multiple Climate Model Errors,” Annals of Applied Statistics, 5, 2519–2548.
- Schlather, M., Malinowski, A., Menck, P. J., Oesting, M., and Strokorb, K. (2015), “Analysis, Simulation and Prediction of Multivariate Random Fields With Package Randomfields,” Journal of Statistical Software, 63, 1–25.
- Shaby, B. A., and Ruppert, D. (2012), “Tapered Covariance: Bayesian Estimation and Asymptotics,” Journal of Computational and Graphical Statistics, 21, 433–452.
- Sherman, J., and Morrison, W. (1950), “Adjustment of an Inverse Matrix Corresponding to a Change in One Element of a Given Matrix,” Annals of Mathematical Statistics, 21, 124–127.
- Snelson, E., and Ghahramani, Z. (2007), “Local and Global Sparse Gaussian Process Approximations,” in Artificial Intelligence and Statistics 11 (AISTATS).
- Stein, M. L. (2011), “2010 Rietz Lecture: When Does the Screening Effect Hold?,” Annals of Statistics, 39, 2795–2819.
- ——— (2014), “Limitations on Low Rank Approximations for Covariance Matrices of Spatial Data,” Spatial Statistics, 8, 1–19.
- Stein, M. L., Chen, J., and Anitescu, M. (2013), “Stochastic Approximation of Score Functions for Gaussian Processes,” The Annals of Applied Statistics, 7, 1162–1191.
- Stein, M. L., Chi, Z., and Welty, L. (2004), “Approximating Likelihoods for Large Spatial Data Sets,” Journal of the Royal Statistical Society, Series B, 66, 275–296.
- Vecchia, A. (1988), “Estimation and Model Identification for Continuous Spatial Processes,” Journal of the Royal Statistical Society, Series B, 50, 297–312.
- Woodbury, M. (1950), “Inverting Modified Matrices,” Memorandum Report 42, Statistical Research Group, Princeton, NJ: Princeton University.