Complexity analysis of accelerated MCMC methods for Bayesian inversion
The Bayesian approach to inverse problems, in which the posterior probability distribution on an unknown field is sampled for the purposes of computing posterior expectations of quantities of interest, is starting to become computationally feasible for partial differential equation (PDE) inverse pr...
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sg-ntu-dr.10356-1013722020-03-07T12:34:45Z Complexity analysis of accelerated MCMC methods for Bayesian inversion Hoang, Viet Ha. Schwab, Christoph. Stuart, Andrew M. School of Physical and Mathematical Sciences DRNTU::Science::Mathematics::Discrete mathematics::Algorithms The Bayesian approach to inverse problems, in which the posterior probability distribution on an unknown field is sampled for the purposes of computing posterior expectations of quantities of interest, is starting to become computationally feasible for partial differential equation (PDE) inverse problems. Balancing the sources of error arising from finite-dimensional approximation of the unknown field, the PDE forward solution map and the sampling of the probability space under the posterior distribution are essential for the design of efficient computational Bayesian methods for PDE inverse problems. We study Bayesian inversion for a model elliptic PDE with an unknown diffusion coefficient. We provide complexity analyses of several Markov chain Monte Carlo (MCMC) methods for the efficient numerical evaluation of expectations under the Bayesian posterior distribution, given data δ. Particular attention is given to bounds on the overall work required to achieve a prescribed error level ε. Specifically,we first bound the computational complexity of ‘plain’ MCMC, based on combining MCMC sampling with linear complexity multi-level solvers for elliptic PDE. Our (new) work versus accuracy bounds show that the complexity of this approach can be quite prohibitive. Two strategies for reducing the computational complexity are then proposed and analyzed: first, a sparse, parametric and deterministic generalized polynomial chaos (gpc) ‘surrogate’ representation of the forward response map of the PDE over the entire parameter space, and, second, a novel multi-level Markov chainMonte Carlo strategy which utilizes sampling from a multi-level discretization of the posterior and the forward PDE. For both of these strategies, we derive asymptotic bounds on work versus accuracy, and hence asymptotic bounds on the computational complexity of the algorithms. In particular, we provide sufficient conditions on the regularity of the unknown coefficients of the PDE and on the approximation methods used, in order for the accelerations of MCMC resulting from these strategies to lead to complexity reductions over ‘plain’ MCMC algorithms for the Bayesian inversion of PDEs. 2014-01-27T07:02:17Z 2019-12-06T20:37:23Z 2014-01-27T07:02:17Z 2019-12-06T20:37:23Z 2013 2013 Journal Article Hoang, V. H., Schwab, C., & Stuart, A. M. (2013). Complexity analysis of accelerated MCMC methods for Bayesian inversion. Inverse Problems, 29(8). https://hdl.handle.net/10356/101372 http://hdl.handle.net/10220/18708 10.1088/0266-5611/29/8/085010 en Inverse problems © 2013 IOP Publishing Ltd. 38 p. |
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DRNTU::Science::Mathematics::Discrete mathematics::Algorithms Hoang, Viet Ha. Schwab, Christoph. Stuart, Andrew M. Complexity analysis of accelerated MCMC methods for Bayesian inversion |
| description |
The Bayesian approach to inverse problems, in which the posterior probability distribution on an unknown field is sampled for the purposes of computing posterior expectations of quantities of interest, is starting to become computationally feasible for partial differential equation (PDE) inverse
problems. Balancing the sources of error arising from finite-dimensional approximation of the unknown field, the PDE forward solution map and the sampling of the probability space under the posterior distribution are essential for the design of efficient computational Bayesian methods for PDE inverse problems. We study Bayesian inversion for a model elliptic PDE with an unknown diffusion coefficient. We provide complexity analyses of several Markov chain Monte Carlo (MCMC) methods for the efficient numerical evaluation of expectations under the Bayesian posterior distribution, given
data δ. Particular attention is given to bounds on the overall work required to achieve a prescribed error level ε. Specifically,we first bound the computational complexity of ‘plain’ MCMC, based on combining MCMC sampling with
linear complexity multi-level solvers for elliptic PDE. Our (new) work versus accuracy bounds show that the complexity of this approach can be quite prohibitive. Two strategies for reducing the computational complexity are then proposed and analyzed: first, a sparse, parametric and deterministic generalized polynomial chaos (gpc) ‘surrogate’ representation of the forward response map of the PDE over the entire parameter space, and, second, a novel multi-level Markov chainMonte Carlo strategy which utilizes sampling from a multi-level discretization of the posterior and the forward PDE. For both of these strategies, we derive asymptotic bounds on work versus accuracy, and hence asymptotic bounds on the computational complexity of the algorithms. In particular, we
provide sufficient conditions on the regularity of the unknown coefficients of the PDE and on the approximation methods used, in order for the accelerations of MCMC resulting from these strategies to lead to complexity reductions over
‘plain’ MCMC algorithms for the Bayesian inversion of PDEs. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Hoang, Viet Ha. Schwab, Christoph. Stuart, Andrew M. |
| format |
Article |
| author |
Hoang, Viet Ha. Schwab, Christoph. Stuart, Andrew M. |
| author_sort |
Hoang, Viet Ha. |
| title |
Complexity analysis of accelerated MCMC methods for Bayesian inversion |
| title_short |
Complexity analysis of accelerated MCMC methods for Bayesian inversion |
| title_full |
Complexity analysis of accelerated MCMC methods for Bayesian inversion |
| title_fullStr |
Complexity analysis of accelerated MCMC methods for Bayesian inversion |
| title_full_unstemmed |
Complexity analysis of accelerated MCMC methods for Bayesian inversion |
| title_sort |
complexity analysis of accelerated mcmc methods for bayesian inversion |
| publishDate |
2014 |
| url |
https://hdl.handle.net/10356/101372 http://hdl.handle.net/10220/18708 |
| _version_ |
1681049545358704640 |