Bayesian nonparametric statistics

Useful stochastic processes
Posterior updates in infinite dimesnions
Bayesian consistency
Incoming
References

It is hard to explain what happens to the posterior in this case

Useful stochastic processes

A map of popular processes used in Bayesian nonparametrics from Xuan, Lu, and Zhang (2020)

Dirichlet priors, other measure priors, Gaussian Process regression, reparameterisations etc. 🏗

Posterior updates in infinite dimesnions

For now, this is just a bookmark to the general measure theoretic notation that unifies, in principle, the various Bayesian nonparametric methods. A textbook on general theory is Schervish (2012). Chapter 1 of Matthews (2017) is a compact introduction.

Particular applications are outlined in Matthews (2017) (GP regression) and Stuart (2010) (inverse problems).

A brief introduction the kind of measure-theoretic notation we need in the infinite-dimensional Hilbert space settings is in Alexanderian (2021), giving Bayes’ formula as \[ \frac{d \mu_{\text {post }}^{y}}{d \mu_{\text {pr }}} \propto \pi_{\text {like }}(\boldsymbol{y} \mid m), \] where the left hand side is the Radon-Nikodym derivative of \(\mu_{\text {post }}^{y}\) with respect to \(\mu_{\text {pr }}\).

They observe

Note that in the finite-dimensional setting the abstract form of the Bayes’ formula above can be reduced to the familiar form of Bayes’ formula in terms of PDFs. Specifically, working in finite-dimensions, with \(\mu_{\mathrm{pr}}\) and \(\mu_{\mathrm{post}}^{y}\) that are absolutely continuous with respect to the Lebesgue measure \(\lambda\), the prior and posterior measures admit Lebesgue densities \(\pi_{\mathrm{pr}}\) and \(\pi_{\text {post }}\), respectively. Then, we note \[ \pi_{\mathrm{post}}(m \mid \boldsymbol{y})=\frac{d \mu_{\mathrm{post}}^{y}}{d \lambda}(m)=\frac{d \mu_{\mathrm{post}}^{y}}{d \mu_{\mathrm{pr}}}(m) \frac{d \mu_{\mathrm{pr}}}{d \lambda}(m) \propto \pi_{\mathrm{like}}(\boldsymbol{y} \mid m) \pi_{\mathrm{pr}}(m) \]

Bayesian consistency

Consistency turns out to be potentially tricky for functional models. I am not an expert on consistency, but see Cox (1993) for some warnings about what can go wrong and Florens and Simoni (2016);Knapik, van der Vaart, and van Zanten (2011) for some remedies. tl;dr posterior credible intervals arising from over-tight priors may never cover the frequentist estimate. Further reading on this is in some classic refs [Diaconis and Freedman (1986);Freedman (1999);KleijnMisspecification2006].

Incoming

References

Alexanderian, Alen. 2021. “Optimal Experimental Design for Infinite-Dimensional Bayesian Inverse Problems Governed by PDEs: A Review.” arXiv:2005.12998 [Math], January.

Bui-Thanh, Tan, Omar Ghattas, James Martin, and Georg Stadler. 2013. “A Computational Framework for Infinite-Dimensional Bayesian Inverse Problems Part I: The Linearized Case, with Application to Global Seismic Inversion.” SIAM Journal on Scientific Computing 35 (6): A2494–2523.

Bui-Thanh, Tan, and Quoc P. Nguyen. 2016. “FEM-Based Discretization-Invariant MCMC Methods for PDE-Constrained Bayesian Inverse Problems.” Inverse Problems & Imaging 10 (4): 943.

Cox, Dennis D. 1993. “An Analysis of Bayesian Inference for Nonparametric Regression.” The Annals of Statistics 21 (2): 903–23.

Diaconis, Persi, and David Freedman. 1986. “On the Consistency of Bayes Estimates.” The Annals of Statistics 14 (1): 1–26.

Florens, Jean-Pierre, and Anna Simoni. 2016. “Regularizing Priors for Linear Inverse Problems.” Econometric Theory 32 (1): 71–121.

Freedman, David. 1999. “Wald Lecture: On the Bernstein-von Mises Theorem with Infinite-Dimensional Parameters.” The Annals of Statistics 27 (4): 1119–41.

Kleijn, B. J. K., and A. W. van der Vaart. 2006. “Misspecification in Infinite-Dimensional Bayesian Statistics.” The Annals of Statistics 34 (2): 837–77.

Knapik, B. T., A. W. van der Vaart, and J. H. van Zanten. 2011. “Bayesian Inverse Problems with Gaussian Priors.” The Annals of Statistics 39 (5).

Lee, Hyun Keun, Chulan Kwon, and Yong Woon Kim. 2022. “Statistical Inference as Green’s Functions.” arXiv.

MacEachern, Steven N. 2016. “Nonparametric Bayesian Methods: A Gentle Introduction and Overview.” Communications for Statistical Applications and Methods 23 (6): 445–66.

Matthews, Alexander Graeme de Garis. 2017. “Scalable Gaussian Process Inference Using Variational Methods.” Thesis, University of Cambridge.

Petra, Noemi, James Martin, Georg Stadler, and Omar Ghattas. 2014. “A Computational Framework for Infinite-Dimensional Bayesian Inverse Problems, Part II: Stochastic Newton MCMC with Application to Ice Sheet Flow Inverse Problems.” SIAM Journal on Scientific Computing 36 (4): A1525–55.

Rousseau, Judith. 2016. “On the Frequentist Properties of Bayesian Nonparametric Methods.” Annual Review of Statistics and Its Application 3 (1): 211–31.

Schervish, Mark J. 2012. Theory of Statistics. Springer Series in Statistics. New York, NY: Springer Science & Business Media.

Stuart, Andrew M. 2010. “Inverse Problems: A Bayesian Perspective.” Acta Numerica 19: 451–559.

Szabó, Botond, Aad van der Vaart, and Harry van Zanten. 2013. “Frequentist Coverage of Adaptive Nonparametric Bayesian Credible Sets.” arXiv:1310.4489 [Math, Stat], October.

Xuan, Junyu, Jie Lu, and Guangquan Zhang. 2020. “A Survey on Bayesian Nonparametric Learning.” ACM Computing Surveys 52 (1): 1–36.

Zhou, Mingyuan, Haojun Chen, John Paisley, Lu Ren, Guillermo Sapiro, and Lawrence Carin. 2009. “Non-Parametric Bayesian Dictionary Learning for Sparse Image Representations.” In Proceedings of the 22nd International Conference on Neural Information Processing Systems, 22:2295–2303. NIPS’09. Red Hook, NY, USA: Curran Associates Inc.