Designing a benthic monitoring programme with multiple conflicting objectives

1. Sound conservation and management advice usually requires spatial data on animal and plant abundances. The expense of programmes to determine species distributions and estimates of population sizes often limits sample size. To maximise effectiveness at minimal costs, optimisations of such monitor...

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Published in:Methods in Ecology and Evolution
Main Authors: Bijleveld, A. I., van Gils, J. A., van der Meer, J., Dekinga, A., Kraan, C., van der Veer, H. W., Piersma, T.
Format: Article in Journal/Newspaper
Language:English
Published: 2012
Subjects:
generalised least squares
intertidal
landscape ecology
macrobenthic invertebrates
model-based inference
power analysis
spatial autocorrelation
spatial autocorrelation function
KNOTS CALIDRIS-CANUTUS
CERASTODERMA-EDULE
INTERTIDAL FLATS
SAMPLING DESIGN
LANDSCAPE-SCALE
PATCH-CHOICE
LONG-TERM
POPULATION
BIVALVE
Calidris canutus
Online Access:https://hdl.handle.net/11370/a3e4aebe-38bf-49e7-b88a-c29ff3996ea6
https://research.rug.nl/en/publications/a3e4aebe-38bf-49e7-b88a-c29ff3996ea6
https://doi.org/10.1111/j.2041-210X.2012.00192.x
id ftunigroningenpu:oai:pure.rug.nl:publications/a3e4aebe-38bf-49e7-b88a-c29ff3996ea6
record_format openpolar
spelling ftunigroningenpu:oai:pure.rug.nl:publications/a3e4aebe-38bf-49e7-b88a-c29ff3996ea6 2024-06-23T07:51:56+00:00 Designing a benthic monitoring programme with multiple conflicting objectives Bijleveld, A. I. van Gils, J. A. van der Meer, J. Dekinga, A. Kraan, C. van der Veer, H. W. Piersma, T. 2012-06 https://hdl.handle.net/11370/a3e4aebe-38bf-49e7-b88a-c29ff3996ea6 https://research.rug.nl/en/publications/a3e4aebe-38bf-49e7-b88a-c29ff3996ea6 https://doi.org/10.1111/j.2041-210X.2012.00192.x eng eng https://research.rug.nl/en/publications/a3e4aebe-38bf-49e7-b88a-c29ff3996ea6 info:eu-repo/semantics/closedAccess Bijleveld , A I , van Gils , J A , van der Meer , J , Dekinga , A , Kraan , C , van der Veer , H W & Piersma , T 2012 , ' Designing a benthic monitoring programme with multiple conflicting objectives ' , Methods in ecology and evolution , vol. 3 , no. 3 , pp. 526-536 . https://doi.org/10.1111/j.2041-210X.2012.00192.x generalised least squares intertidal landscape ecology macrobenthic invertebrates model-based inference power analysis spatial autocorrelation spatial autocorrelation function KNOTS CALIDRIS-CANUTUS CERASTODERMA-EDULE INTERTIDAL FLATS SAMPLING DESIGN LANDSCAPE-SCALE PATCH-CHOICE LONG-TERM POPULATION BIVALVE article 2012 ftunigroningenpu https://doi.org/10.1111/j.2041-210X.2012.00192.x 2024-05-27T16:05:39Z 1. Sound conservation and management advice usually requires spatial data on animal and plant abundances. The expense of programmes to determine species distributions and estimates of population sizes often limits sample size. To maximise effectiveness at minimal costs, optimisations of such monitoring efforts are critical. A monitoring programme can have multiple objectives with demands on the optimal sampling design that are often in conflict. Here, we develop an optimal sampling design for monitoring programmes with conflicting objectives, building on an existing intertidal benthic monitoring programme in the Dutch Wadden Sea and simulation models bounded in their parameter spaces by these data. 2. We distinguish three possible objectives: (1) estimation of temporal changes and spatial differences in abundance and (2) mapping, that is, prediction of abundances at unsampled locations. Mapping abundances requires model-based analyses using autocorrelation models. Such analyses are as good as the model fits the data; therefore, the final objective was (3) accurately estimating model autocorrelation parameters. To compare sampling designs, we used the following criteria: (1) minimum detectable difference in mean between two time periods or two areas, (2) mean prediction error and (3) estimation bias of autocorrelation parameters. 3. Using Monte Carlo simulations, we compared five sampling designs with respect to these criteria (i.e. simple random, grid, two types of transects, and grid with random replacements) at four levels of naturally occurring spatial autocorrelation. 4. The ideal sampling design for objectives (1) and (2) was grid sampling and for objective (3) random sampling. The sampling design that catered best for all three objectives combined was grid sampling with a number of random samples placed on gridlines. 5. Grid sampling with a number of random samples is considered an accurate and powerful tool with the highest effectiveness. This sampling design is widely applicable and allows for accurate ... Article in Journal/Newspaper Calidris canutus University of Groningen research database Methods in Ecology and Evolution 3 3 526 536
institution Open Polar
collection University of Groningen research database
op_collection_id ftunigroningenpu
language English
topic generalised least squares
intertidal
landscape ecology
macrobenthic invertebrates
model-based inference
power analysis
spatial autocorrelation
spatial autocorrelation function
KNOTS CALIDRIS-CANUTUS
CERASTODERMA-EDULE
INTERTIDAL FLATS
SAMPLING DESIGN
LANDSCAPE-SCALE
PATCH-CHOICE
LONG-TERM
POPULATION
BIVALVE
spellingShingle generalised least squares
intertidal
landscape ecology
macrobenthic invertebrates
model-based inference
power analysis
spatial autocorrelation
spatial autocorrelation function
KNOTS CALIDRIS-CANUTUS
CERASTODERMA-EDULE
INTERTIDAL FLATS
SAMPLING DESIGN
LANDSCAPE-SCALE
PATCH-CHOICE
LONG-TERM
POPULATION
BIVALVE
Bijleveld, A. I.
van Gils, J. A.
van der Meer, J.
Dekinga, A.
Kraan, C.
van der Veer, H. W.
Piersma, T.
Designing a benthic monitoring programme with multiple conflicting objectives
topic_facet generalised least squares
intertidal
landscape ecology
macrobenthic invertebrates
model-based inference
power analysis
spatial autocorrelation
spatial autocorrelation function
KNOTS CALIDRIS-CANUTUS
CERASTODERMA-EDULE
INTERTIDAL FLATS
SAMPLING DESIGN
LANDSCAPE-SCALE
PATCH-CHOICE
LONG-TERM
POPULATION
BIVALVE
description 1. Sound conservation and management advice usually requires spatial data on animal and plant abundances. The expense of programmes to determine species distributions and estimates of population sizes often limits sample size. To maximise effectiveness at minimal costs, optimisations of such monitoring efforts are critical. A monitoring programme can have multiple objectives with demands on the optimal sampling design that are often in conflict. Here, we develop an optimal sampling design for monitoring programmes with conflicting objectives, building on an existing intertidal benthic monitoring programme in the Dutch Wadden Sea and simulation models bounded in their parameter spaces by these data. 2. We distinguish three possible objectives: (1) estimation of temporal changes and spatial differences in abundance and (2) mapping, that is, prediction of abundances at unsampled locations. Mapping abundances requires model-based analyses using autocorrelation models. Such analyses are as good as the model fits the data; therefore, the final objective was (3) accurately estimating model autocorrelation parameters. To compare sampling designs, we used the following criteria: (1) minimum detectable difference in mean between two time periods or two areas, (2) mean prediction error and (3) estimation bias of autocorrelation parameters. 3. Using Monte Carlo simulations, we compared five sampling designs with respect to these criteria (i.e. simple random, grid, two types of transects, and grid with random replacements) at four levels of naturally occurring spatial autocorrelation. 4. The ideal sampling design for objectives (1) and (2) was grid sampling and for objective (3) random sampling. The sampling design that catered best for all three objectives combined was grid sampling with a number of random samples placed on gridlines. 5. Grid sampling with a number of random samples is considered an accurate and powerful tool with the highest effectiveness. This sampling design is widely applicable and allows for accurate ...
format Article in Journal/Newspaper
author Bijleveld, A. I.
van Gils, J. A.
van der Meer, J.
Dekinga, A.
Kraan, C.
van der Veer, H. W.
Piersma, T.
author_facet Bijleveld, A. I.
van Gils, J. A.
van der Meer, J.
Dekinga, A.
Kraan, C.
van der Veer, H. W.
Piersma, T.
author_sort Bijleveld, A. I.
title Designing a benthic monitoring programme with multiple conflicting objectives
title_short Designing a benthic monitoring programme with multiple conflicting objectives
title_full Designing a benthic monitoring programme with multiple conflicting objectives
title_fullStr Designing a benthic monitoring programme with multiple conflicting objectives
title_full_unstemmed Designing a benthic monitoring programme with multiple conflicting objectives
title_sort designing a benthic monitoring programme with multiple conflicting objectives
publishDate 2012
url https://hdl.handle.net/11370/a3e4aebe-38bf-49e7-b88a-c29ff3996ea6
https://research.rug.nl/en/publications/a3e4aebe-38bf-49e7-b88a-c29ff3996ea6
https://doi.org/10.1111/j.2041-210X.2012.00192.x
genre Calidris canutus
genre_facet Calidris canutus
op_source Bijleveld , A I , van Gils , J A , van der Meer , J , Dekinga , A , Kraan , C , van der Veer , H W & Piersma , T 2012 , ' Designing a benthic monitoring programme with multiple conflicting objectives ' , Methods in ecology and evolution , vol. 3 , no. 3 , pp. 526-536 . https://doi.org/10.1111/j.2041-210X.2012.00192.x
op_relation https://research.rug.nl/en/publications/a3e4aebe-38bf-49e7-b88a-c29ff3996ea6
op_rights info:eu-repo/semantics/closedAccess
op_doi https://doi.org/10.1111/j.2041-210X.2012.00192.x
container_title Methods in Ecology and Evolution
container_volume 3
container_issue 3
container_start_page 526
op_container_end_page 536
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