Marginalising posterior covariance matrix with application to Bayesian operational modal analysis
Consider making Bayesian inference of vector-valued model parameters {x,y} based on observed data D. When the ‘posterior’ (i.e., given data) probability density function (PDF) of {x,y} has a centralised shape, it can be approximated in the spirit of Laplace integral asymptotics by a Gaussian PDF cen...
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sg-ntu-dr.10356-1808912024-11-08T15:35:00Z Marginalising posterior covariance matrix with application to Bayesian operational modal analysis Au, Siu-Kui School of Civil and Environmental Engineering Engineering Maximum likelihood BAYOMA Block matrix inverse Fisher information matrix Marginalisation Consider making Bayesian inference of vector-valued model parameters {x,y} based on observed data D. When the ‘posterior’ (i.e., given data) probability density function (PDF) of {x,y} has a centralised shape, it can be approximated in the spirit of Laplace integral asymptotics by a Gaussian PDF centred at the ‘most probable value’ (MPV) that minimises the objective function L(x,y)=-ln[p(D|x,y)p(x,y)], where p(D|x,y) is the likelihood function and p(x,y) is the prior PDF. The ‘posterior covariance matrix’ of {x,y} that reflects the remaining uncertainty after using data is then equal to the inverse of the Hessian of L(x,y) at the MPV. Suppose the ‘partial MPV’ y ̂(x) is available, so that ∂L\/∂y=0 for any x as long as y=y ̂(x). Correspondingly, the ‘partially minimised’ objective function that depends only on x is defined as L ̂(x)=L(x,y ̂(x)). In the above context, this article shows that the posterior covariance matrix of x can be obtained as the inverse of the Hessian of L ̂(x) at the MPV. That is, the marginalisation of y in MPV can be carried over to the covariance matrix. The result can also be extended to the inverse of Fisher information matrix, which gives the large-sample asymptotic form of the posterior covariance matrix when there is no modelling error. The theory is applied to operational modal analysis with well-separated modes, providing an alternative means to conventional approach for evaluating the posterior covariance matrix of spectral parameters (e.g., frequency, damping) after marginalising out spatial parameters such as the mode shape. Issues of theoretical and computational nature are discussed and verified by synthetic, laboratory and field data. Ministry of Education (MOE) Submitted/Accepted version The research presented in this paper is supported by Academic Research Fund Tier 1 (RG68/22) from the Ministry of Education, Singapore. 2024-11-05T04:25:25Z 2024-11-05T04:25:25Z 2025 Journal Article Au, S. (2025). Marginalising posterior covariance matrix with application to Bayesian operational modal analysis. Mechanical Systems and Signal Processing, 224, 112051-. https://dx.doi.org/10.1016/j.ymssp.2024.112051 0888-3270 https://hdl.handle.net/10356/180891 10.1016/j.ymssp.2024.112051 224 112051 en RG68/22 Mechanical Systems and Signal Processing © 2024 Elsevier Ltd. All rights reserved. This article may be downloaded for personal use only. Any other use requires prior permission of the copyright holder. The Version of Record is available online at http://doi.org/10.1016/j.ymssp.2024.112051. application/pdf |
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Engineering Maximum likelihood BAYOMA Block matrix inverse Fisher information matrix Marginalisation |
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Engineering Maximum likelihood BAYOMA Block matrix inverse Fisher information matrix Marginalisation Au, Siu-Kui Marginalising posterior covariance matrix with application to Bayesian operational modal analysis |
| description |
Consider making Bayesian inference of vector-valued model parameters {x,y} based on observed data D. When the ‘posterior’ (i.e., given data) probability density function (PDF) of {x,y} has a centralised shape, it can be approximated in the spirit of Laplace integral asymptotics by a Gaussian PDF centred at the ‘most probable value’ (MPV) that minimises the objective function L(x,y)=-ln[p(D|x,y)p(x,y)], where p(D|x,y) is the likelihood function and p(x,y) is the prior PDF. The ‘posterior covariance matrix’ of {x,y} that reflects the remaining uncertainty after using data is then equal to the inverse of the Hessian of L(x,y) at the MPV. Suppose the ‘partial MPV’ y ̂(x) is available, so that ∂L\/∂y=0 for any x as long as y=y ̂(x). Correspondingly, the ‘partially minimised’ objective function that depends only on x is defined as L ̂(x)=L(x,y ̂(x)). In the above context, this article shows that the posterior covariance matrix of x can be obtained as the inverse of the Hessian of L ̂(x) at the MPV. That is, the marginalisation of y in MPV can be carried over to the covariance matrix. The result can also be extended to the inverse of Fisher information matrix, which gives the large-sample asymptotic form of the posterior covariance matrix when there is no modelling error. The theory is applied to operational modal analysis with well-separated modes, providing an alternative means to conventional approach for evaluating the posterior covariance matrix of spectral parameters (e.g., frequency, damping) after marginalising out spatial parameters such as the mode shape. Issues of theoretical and computational nature are discussed and verified by synthetic, laboratory and field data. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Au, Siu-Kui |
| format |
Article |
| author |
Au, Siu-Kui |
| author_sort |
Au, Siu-Kui |
| title |
Marginalising posterior covariance matrix with application to Bayesian operational modal analysis |
| title_short |
Marginalising posterior covariance matrix with application to Bayesian operational modal analysis |
| title_full |
Marginalising posterior covariance matrix with application to Bayesian operational modal analysis |
| title_fullStr |
Marginalising posterior covariance matrix with application to Bayesian operational modal analysis |
| title_full_unstemmed |
Marginalising posterior covariance matrix with application to Bayesian operational modal analysis |
| title_sort |
marginalising posterior covariance matrix with application to bayesian operational modal analysis |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/180891 |
| _version_ |
1816858920008810496 |