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Generative models and Bayesian inversion using Laplace approximation

Author

Listed:
  • Manuel Marschall

    (Physikalisch-Technische Bundesanstalt)

  • Gerd Wübbeler

    (Physikalisch-Technische Bundesanstalt)

  • Franko Schmähling

    (Physikalisch-Technische Bundesanstalt)

  • Clemens Elster

    (Physikalisch-Technische Bundesanstalt)

Abstract

The Bayesian approach to solving inverse problems relies on the choice of a prior. This critical ingredient allows expert knowledge or physical constraints to be formulated in a probabilistic fashion and plays an important role for the success of the inference. Recently, Bayesian inverse problems were solved using generative models as highly informative priors. Generative models are a popular tool in machine learning to generate data whose properties closely resemble those of a given database. Typically, the generated distribution of data is embedded in a low-dimensional manifold. For the inverse problem, a generative model is trained on a database that reflects the properties of the sought solution, such as typical structures of the tissue in the human brain in magnetic resonance imaging. The inference is carried out in the low-dimensional manifold determined by the generative model that strongly reduces the dimensionality of the inverse problem. However, this procedure produces a posterior that does not admit a Lebesgue density in the actual variables and the accuracy attained can strongly depend on the quality of the generative model. For linear Gaussian models, we explore an alternative Bayesian inference based on probabilistic generative models; this inference is carried out in the original high-dimensional space. A Laplace approximation is employed to analytically derive the prior probability density function required, which is induced by the generative model. Properties of the resulting inference are investigated. Specifically, we show that derived Bayes estimates are consistent, in contrast to the approach in which the low-dimensional manifold of the generative model is employed. The MNIST data set is used to design numerical experiments that confirm our theoretical findings. It is shown that the approach proposed can be advantageous when the information contained in the data is high and a simple heuristic is considered for the detection of this case. Finally, the pros and cons of both approaches are discussed.

Suggested Citation

  • Manuel Marschall & Gerd Wübbeler & Franko Schmähling & Clemens Elster, 2024. "Generative models and Bayesian inversion using Laplace approximation," Computational Statistics, Springer, vol. 39(3), pages 1321-1349, May.
    • Handle: RePEc:spr:compst:v:39:y:2024:i:3:d:10.1007_s00180-023-01345-5
    DOI: 10.1007/s00180-023-01345-5
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    References listed on IDEAS

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    1. Smith, Michael & Fahrmeir, Ludwig, 2007. "Spatial Bayesian Variable Selection With Application to Functional Magnetic Resonance Imaging," Journal of the American Statistical Association, American Statistical Association, vol. 102, pages 417-431, June.
    2. repec:dau:papers:123456789/1908 is not listed on IDEAS
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