Robust A-Optimal Experimental Design for Bayesian Inverse Problems
- URL: http://arxiv.org/abs/2305.03855v1
- Date: Fri, 5 May 2023 21:43:00 GMT
- Title: Robust A-Optimal Experimental Design for Bayesian Inverse Problems
- Authors: Ahmed Attia and Sven Leyffer and Todd Munson
- Abstract summary: An optimal design maximizes a predefined utility function that is formulated in terms of the elements of an inverse problem.
This work presents an efficient algorithmic approach for designing optimal experimental design schemes for Bayesian inverse problems.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Optimal design of experiments for Bayesian inverse problems has recently
gained wide popularity and attracted much attention, especially in the
computational science and Bayesian inversion communities. An optimal design
maximizes a predefined utility function that is formulated in terms of the
elements of an inverse problem, an example being optimal sensor placement for
parameter identification. The state-of-the-art algorithmic approaches following
this simple formulation generally overlook misspecification of the elements of
the inverse problem, such as the prior or the measurement uncertainties. This
work presents an efficient algorithmic approach for designing optimal
experimental design schemes for Bayesian inverse problems such that the optimal
design is robust to misspecification of elements of the inverse problem.
Specifically, we consider a worst-case scenario approach for the uncertain or
misspecified parameters, formulate robust objectives, and propose an
algorithmic approach for optimizing such objectives. Both relaxation and
stochastic solution approaches are discussed with detailed analysis and insight
into the interpretation of the problem and the proposed algorithmic approach.
Extensive numerical experiments to validate and analyze the proposed approach
are carried out for sensor placement in a parameter identification problem.
Related papers
- A Probabilistic Approach to Trajectory-Based Optimal Experimental Design [0.0]
We present a novel probabilistic approach for optimal path experimental design.<n>In this approach a discrete path optimization problem is defined on a static navigation mesh.<n> trajectories are modeled as random variables governed by a parametric Markov policy.
arXiv Detail & Related papers (2026-01-16T17:58:16Z) - BO4IO: A Bayesian optimization approach to inverse optimization with uncertainty quantification [5.031974232392534]
This work addresses data-driven inverse optimization (IO)
The goal is to estimate unknown parameters in an optimization model from observed decisions that can be assumed to be optimal or near-optimal.
arXiv Detail & Related papers (2024-05-28T06:52:17Z) - Enhancing Gaussian Process Surrogates for Optimization and Posterior Approximation via Random Exploration [2.984929040246293]
novel noise-free Bayesian optimization strategies that rely on a random exploration step to enhance the accuracy of Gaussian process surrogate models.
New algorithms retain the ease of implementation of the classical GP-UCB, but an additional exploration step facilitates their convergence.
arXiv Detail & Related papers (2024-01-30T14:16:06Z) - Generalizing Bayesian Optimization with Decision-theoretic Entropies [102.82152945324381]
We consider a generalization of Shannon entropy from work in statistical decision theory.
We first show that special cases of this entropy lead to popular acquisition functions used in BO procedures.
We then show how alternative choices for the loss yield a flexible family of acquisition functions.
arXiv Detail & Related papers (2022-10-04T04:43:58Z) - Amortized Implicit Differentiation for Stochastic Bilevel Optimization [53.12363770169761]
We study a class of algorithms for solving bilevel optimization problems in both deterministic and deterministic settings.
We exploit a warm-start strategy to amortize the estimation of the exact gradient.
By using this framework, our analysis shows these algorithms to match the computational complexity of methods that have access to an unbiased estimate of the gradient.
arXiv Detail & Related papers (2021-11-29T15:10:09Z) - A novel multiobjective evolutionary algorithm based on decomposition and
multi-reference points strategy [14.102326122777475]
Multiobjective evolutionary algorithm based on decomposition (MOEA/D) has been regarded as a significantly promising approach for solving multiobjective optimization problems (MOPs)
We propose an improved MOEA/D algorithm by virtue of the well-known Pascoletti-Serafini scalarization method and a new strategy of multi-reference points.
arXiv Detail & Related papers (2021-10-27T02:07:08Z) - Outlier-Robust Sparse Estimation via Non-Convex Optimization [73.18654719887205]
We explore the connection between high-dimensional statistics and non-robust optimization in the presence of sparsity constraints.
We develop novel and simple optimization formulations for these problems.
As a corollary, we obtain that any first-order method that efficiently converges to station yields an efficient algorithm for these tasks.
arXiv Detail & Related papers (2021-09-23T17:38:24Z) - Robust Topology Optimization Using Multi-Fidelity Variational Autoencoders [1.0124625066746595]
A robust topology optimization (RTO) problem identifies a design with the best average performance.
A neural network method is proposed that offers computational efficiency.
Numerical application of the method is shown on the robust design of L-bracket structure with single point load as well as multiple point loads.
arXiv Detail & Related papers (2021-07-19T20:40:51Z) - Stochastic Learning Approach to Binary Optimization for Optimal Design
of Experiments [0.0]
We present a novel approach to binary optimization for optimal experimental design (OED) for Bayesian inverse problems governed by mathematical models such as partial differential equations.
The OED utility function, namely, the regularized optimality gradient, is cast into an objective function in the form of an expectation over a Bernoulli distribution.
The objective is then solved by using a probabilistic optimization routine to find an optimal observational policy.
arXiv Detail & Related papers (2021-01-15T03:54:12Z) - Sequential Subspace Search for Functional Bayesian Optimization
Incorporating Experimenter Intuition [63.011641517977644]
Our algorithm generates a sequence of finite-dimensional random subspaces of functional space spanned by a set of draws from the experimenter's Gaussian Process.
Standard Bayesian optimisation is applied on each subspace, and the best solution found used as a starting point (origin) for the next subspace.
We test our algorithm in simulated and real-world experiments, namely blind function matching, finding the optimal precipitation-strengthening function for an aluminium alloy, and learning rate schedule optimisation for deep networks.
arXiv Detail & Related papers (2020-09-08T06:54:11Z) - Optimal Bayesian experimental design for subsurface flow problems [77.34726150561087]
We propose a novel approach for development of chaos expansion (PCE) surrogate model for the design utility function.
This novel technique enables the derivation of a reasonable quality response surface for the targeted objective function with a computational budget comparable to several single-point evaluations.
arXiv Detail & Related papers (2020-08-10T09:42:59Z) - Convergence of adaptive algorithms for weakly convex constrained
optimization [59.36386973876765]
We prove the $mathcaltilde O(t-1/4)$ rate of convergence for the norm of the gradient of Moreau envelope.
Our analysis works with mini-batch size of $1$, constant first and second order moment parameters, and possibly smooth optimization domains.
arXiv Detail & Related papers (2020-06-11T17:43:19Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.