Abstract
1 Sequential sampling is attractive because it permits the user to choose, and efficiently achieve, desired confidence interval lengths. Sequential sampling has been broadly applied in the inventory of ecological resources. 2 Using case studies and simulations, we demonstrate that estimates of the population mean that are derived from sequential sampling can be overconfident if the population is autocorrelated, that is, that the confidence intervals are too short. We test a model-based correction designed to ameliorate this effect of autocorrelation upon the estimates of confidence intervals from sequential sampling. 3 The correction is useful in realistic situations. Among the scenarios we tested, better confidence interval coverage was achieved with larger sample sizes, and coverage rates were poor at smaller sample sizes. Nominal coverage could be attained even when the wrong model was used, although only at the cost of requiring a much higher average sample size. 4 Synthesis and applications. If sequential sampling is naively applied in a population that has autocorrelation, then confidence intervals for population parameters will be too short, and the usefulness of the sample will be overestimated. We recommend using a correction to lengthen the estimated confidence intervals. Our results suggest that this correction requires a substantial sample size, up to several hundred units, in order to provide nominal coverage. Sequential sampling seems risky in autocorrelated populations if the realized sample size is small.
Keywords
StatisticsConfidence intervalSampling (signal processing)AutocorrelationSample size determinationSample (material)PopulationMathematicsEconometricsSampling designPopulation sizeComputer scienceDemography
Affiliated Institutions
Related Publications
Empirical Size, Coverage, and Power of Confidence Intervals for Spearman's Rho
Several methods of constructing confidence intervals (CIs) for Spearman's rho were tested in a Monte Carlo investigation. A total of 2,000 samples of sizes 10, 50, and 200 were ...
CONFIDENCE LIMITS ON PHYLOGENIES: AN APPROACH USING THE BOOTSTRAP
The recently-developed statistical method known as the "bootstrap" can be used to place confidence intervals on phylogenies. It involves resampling points from one's own data, w...
On the Sampling Interpretation of Confidence Intervals and Hypothesis Tests in the Context of Conditional Maximum Likelihood Estimation
In the context of conditional maximum likelihood (CML) estimation, confidence intervals can be interpreted in three different ways, depending on the sampling distribution under ...
Balanced Simultaneous Confidence Sets
Abstract Suppose that T(θ) = {Tu (θ)} is a family of parametric functions indexed by the variable u. For each u, an approximate confidence set Cn,u for Tu (θ) may be obtained by...
Trim and Fill: A Simple Funnel‐Plot–Based Method of Testing and Adjusting for Publication Bias in Meta‐Analysis
Summary. We study recently developed nonparametric methods for estimating the number of missing studies that might exist in a meta‐analysis and the effect that these studies mig...
Publication Info
- Year
- 2008
- Type
- article
- Volume
- 45
- Issue
- 4
- Pages
- 1221-1227
- Citations
- 1
- Access
- Closed
External Links
Social Impact
Altmetric
PlumX Metrics
Social media, news, blog, policy document mentions
Citation Metrics
1
OpenAlex
0
Influential
1
CrossRef
Cite This
Andrew P. Robinson,
Jeff D. Hamann
(2008).
Correcting for spatial autocorrelation in sequential sampling.
Journal of Applied Ecology
, 45
(4)
, 1221-1227.
https://doi.org/10.1111/j.1365-2664.2008.01485.x
Identifiers
- DOI
- 10.1111/j.1365-2664.2008.01485.x