acebayes: An R Package for Bayesian optimal design of experiments via approximate coordinate exchange
acebayes: An R Package for Bayesian optimal design of experiments via approximate coordinate exchange
We describe the R package acebayes and demonstrate its use to find Bayesian optimal experimental designs. A decision-theoretic approach is adopted, with the optimal design maximising an expected utility. Finding Bayesian optimal designs for realistic problems is challenging, as the expected utility is typically intractable and the design space may be high-dimensional. The package implements the approximate coordinate exchange algorithm to optimise (an approximation to) the expected utility via a sequence of conditional one-dimensional optimisation steps. At each step, a Gaussian process regression model is used to approximate, and subsequently optimise, the expected utility as the function of a single design coordinate (the value taken by one controllable variable for one run of the experiment). In addition to functions for bespoke design problems with user-defined utility functions, acebayes provides functions tailored to finding designs for common generalised linear and nonlinear models. The package provides a step-change in the complexity of problems that can be addressed, enabling designs to be found for much larger numbers of variables and runs than previously possible. We provide tutorials on the application of the methodology for four illustrative examples of varying complexity where designs are found for the goals of parameter estimation, model selection and prediction. These examples demonstrate previously unseen functionality of acebayes.
Overstall, Antony
c1d6c8bd-1c5f-49ee-a845-ec9ec7b20910
Woods, David
ae21f7e2-29d9-4f55-98a2-639c5e44c79c
Adamou, Maria
233a3fb9-8b76-4d92-8735-2ea6c405bbbc
Overstall, Antony
c1d6c8bd-1c5f-49ee-a845-ec9ec7b20910
Woods, David
ae21f7e2-29d9-4f55-98a2-639c5e44c79c
Adamou, Maria
233a3fb9-8b76-4d92-8735-2ea6c405bbbc
Overstall, Antony, Woods, David and Adamou, Maria
(2019)
acebayes: An R Package for Bayesian optimal design of experiments via approximate coordinate exchange.
Journal of Statistical Software.
(In Press)
Abstract
We describe the R package acebayes and demonstrate its use to find Bayesian optimal experimental designs. A decision-theoretic approach is adopted, with the optimal design maximising an expected utility. Finding Bayesian optimal designs for realistic problems is challenging, as the expected utility is typically intractable and the design space may be high-dimensional. The package implements the approximate coordinate exchange algorithm to optimise (an approximation to) the expected utility via a sequence of conditional one-dimensional optimisation steps. At each step, a Gaussian process regression model is used to approximate, and subsequently optimise, the expected utility as the function of a single design coordinate (the value taken by one controllable variable for one run of the experiment). In addition to functions for bespoke design problems with user-defined utility functions, acebayes provides functions tailored to finding designs for common generalised linear and nonlinear models. The package provides a step-change in the complexity of problems that can be addressed, enabling designs to be found for much larger numbers of variables and runs than previously possible. We provide tutorials on the application of the methodology for four illustrative examples of varying complexity where designs are found for the goals of parameter estimation, model selection and prediction. These examples demonstrate previously unseen functionality of acebayes.
Text
acebayes vignette arXiv
- Accepted Manuscript
Available under License Other.
More information
Accepted/In Press date: 2 June 2019
Identifiers
Local EPrints ID: 431959
URI: http://eprints.soton.ac.uk/id/eprint/431959
PURE UUID: 911aa4b9-3b30-43c1-9678-30a47920c617
Catalogue record
Date deposited: 24 Jun 2019 16:30
Last modified: 16 Mar 2024 03:53
Export record
Contributors
Author:
Maria Adamou
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
