Efficient Model-Based Sequential Designs for Sensitivity Experiments.

Abstract

A sequential design for estimating the percentiles of a quantal response curve is proposed. Its updating rule is based on an efficient summary of all the data available via a parametric model. Its efficiency in terms of saving the number of runs and its robustness against the distributional assumption are demonstrated heuristically and in a simulation study. A linear approximation to the logit-MLE version of the proposed sequential design is shown to be equivalent to an asymptotically optimal stochastic approximation method, thereby providing a large sample justification. For sample size between 12 and 35, the simulation study shows that the logit-MLE version of the general sequential procedure substantially outperforms an adaptive (and asymptotically optimal) version of the Robbins-Monro method, which in turn outperforms the nonadaptive Robbins-Munro and Up-and-Down methods. A nonparametric sequential design, via the Spearman-Karber estimator, for estimating the median is also proposed. (Author)

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Document Details

Document Type
Technical Report
Publication Date
Sep 01, 1983
Accession Number
ADA134573

Entities

People

  • C. F. Jeff Wu

Organizations

  • University of Wisconsin–Madison

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  • Counter IED

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  • Bioassay
  • Computational Science
  • Contracts
  • Data Science
  • Efficiency
  • Equations
  • Estimators
  • Experimental Design
  • Information Science
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  • North Carolina
  • Probability
  • Sensitivity
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  • Statistical Algorithms
  • Statistics
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Fields of Study

  • Mathematics

Readers

  • Adaptive Control and Estimation with Uncertainty in Dynamic Systems.
  • Regression Analysis.