Bias correction and bootstrap methods for a spatial sampling scheme
Bias correction and bootstrap methods for a spatial sampling scheme
Motivated by sampling problems in forestry and related fields, we suggest a spatial sampling scheme for estimating intensity of a point process. The technique is related to the 'wandering quarter' method. In applications where the cost of identifying random points is high relative to the cost of taking measurements, for example when identification involves travelling within a large region, our approach has significant advantages over more traditional approaches such as T-square sampling. When the point process is Poisson we suggest a simple bias correction for a 'naive' estimator of intensity, and also discuss a more complex estimator based on maximum likelihood. A technique for pivoting, founded on a fourth-root transformation, is proposed and shown to yield second-order accuracy when applied to construct bootstrap confidence intervals for intensity. Bootstrap methods for correcting edge effects and for addressing non-Poisson point-process models are also suggested.
boundary effect, confidence interval, edge effect, forestry, intensity estimation, pivotal statistic, Poisson process, T-square sampling, wandering quarter sampling
829-846
Hall, Peter
dcd45cc0-be3e-48f3-b121-346ce12aa25b
Melville, Gavin
d09e7304-4d7d-42a3-9d51-e53f530abc70
Welsh, Alan H.
71e0487b-c019-4405-ae36-59344e063ff5
2001
Hall, Peter
dcd45cc0-be3e-48f3-b121-346ce12aa25b
Melville, Gavin
d09e7304-4d7d-42a3-9d51-e53f530abc70
Welsh, Alan H.
71e0487b-c019-4405-ae36-59344e063ff5
Hall, Peter, Melville, Gavin and Welsh, Alan H.
(2001)
Bias correction and bootstrap methods for a spatial sampling scheme.
Bernoulli, 7 (6), .
Abstract
Motivated by sampling problems in forestry and related fields, we suggest a spatial sampling scheme for estimating intensity of a point process. The technique is related to the 'wandering quarter' method. In applications where the cost of identifying random points is high relative to the cost of taking measurements, for example when identification involves travelling within a large region, our approach has significant advantages over more traditional approaches such as T-square sampling. When the point process is Poisson we suggest a simple bias correction for a 'naive' estimator of intensity, and also discuss a more complex estimator based on maximum likelihood. A technique for pivoting, founded on a fourth-root transformation, is proposed and shown to yield second-order accuracy when applied to construct bootstrap confidence intervals for intensity. Bootstrap methods for correcting edge effects and for addressing non-Poisson point-process models are also suggested.
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Published date: 2001
Keywords:
boundary effect, confidence interval, edge effect, forestry, intensity estimation, pivotal statistic, Poisson process, T-square sampling, wandering quarter sampling
Organisations:
Statistics
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Local EPrints ID: 29939
URI: http://eprints.soton.ac.uk/id/eprint/29939
ISSN: 1350-7265
PURE UUID: b05c3c16-37ea-4604-ac86-1d37cf643c76
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Date deposited: 11 May 2006
Last modified: 08 Jan 2022 06:54
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Contributors
Author:
Peter Hall
Author:
Gavin Melville
Author:
Alan H. Welsh
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