scholarly journals Geostatistical delta-generalized linear mixed models improve precision for estimated abundance indices for West Coast groundfishes

2015 ◽  
Vol 72 (5) ◽  
pp. 1297-1310 ◽  
Author(s):  
James T. Thorson ◽  
Andrew O. Shelton ◽  
Eric J. Ward ◽  
Hans J. Skaug
Keyword(s):  
West Coast ◽  
Catch Rate ◽  
Rate Data ◽  
Geostatistical Model ◽  
Efficient Treatment ◽  
True Value ◽  
Management Procedures ◽  
Geostatistical Models ◽  
Index Standardization ◽  
Stratified Model

AbstractIndices of abundance are the bedrock for stock assessments or empirical management procedures used to manage fishery catches for fish populations worldwide, and are generally obtained by processing catch-rate data. Recent research suggests that geostatistical models can explain a substantial portion of variability in catch rates via the location of samples (i.e. whether located in high- or low-density habitats), and thus use available catch-rate data more efficiently than conventional “design-based” or stratified estimators. However, the generality of this conclusion is currently unknown because geostatistical models are computationally challenging to simulation-test and have not previously been evaluated using multiple species. We develop a new maximum likelihood estimator for geostatistical index standardization, which uses recent improvements in estimation for Gaussian random fields. We apply the model to data for 28 groundfish species off the U.S. West Coast and compare results to a previous “stratified” index standardization model, which accounts for spatial variation using post-stratification of available data. This demonstrates that the stratified model generates a relative index with 60% larger estimation intervals than the geostatistical model. We also apply both models to simulated data and demonstrate (i) that the geostatistical model has well-calibrated confidence intervals (they include the true value at approximately the nominal rate), (ii) that neither model on average under- or overestimates changes in abundance, and (iii) that the geostatistical model has on average 20% lower estimation errors than a stratified model. We therefore conclude that the geostatistical model uses survey data more efficiently than the stratified model, and therefore provides a more cost-efficient treatment for historical and ongoing fish sampling data.

Folly and fantasy in the analysis of spatial catch rate data

2003 ◽  
Vol 60 (12) ◽  
pp. 1433-1436 ◽  
Author(s):  
Carl Walters
Keyword(s):  
Catch Rate ◽  
Population Trends ◽  
Rate Data ◽  
Fishing Activity ◽  
Time Period ◽  
Abundance Indices ◽  
Catch Rates ◽  
Catch Per Effort

Spatial catch per effort data can provide useful indices of population trends provided that they are averaged so as to correct for effects of changes in the distribution of fishing activity. Simple, nonspatial ratio estimates should not be used in such analyses. The averaging for any time period must necessarily make some assumptions about what catch rates would have been in spatial strata that had not yet, or were no longer, being fished. Ignoring the unfished strata (averaging only over the areas that were fished) amounts to assuming that they behaved the same as the fished strata and can lead to severe hyperdepletion in abundance indices for fisheries that developed progressively over large regions.

scholarly journals Using catch rate data for simple cost-effective quota setting in the Australian spanner crab (Ranina ranina) fishery

2010 ◽  
Vol 67 (8) ◽  
pp. 1538-1552 ◽  
Author(s):  
Michael F. O'Neill ◽  
Alexander B. Campbell ◽  
Ian W. Brown ◽  
Ron Johnstone
Keyword(s):  
Decision Rules ◽  
Cost Effective ◽  
Catch Rate ◽  
Management Decision ◽  
Rate Data ◽  
Total Allowable Catch ◽  
Management Procedure ◽  
Annual Total ◽  
New Methodologies ◽  
Catch Rates

Abstract O'Neill, M. F., Campbell, A. B., Brown, I. W., and Johnstone, R. 2010. Using catch rate data for simple cost-effective quota setting in the Australian spanner crab (Ranina ranina) fishery. – ICES Journal of Marine Science, 67: 1538–1552. For many fisheries, there is a need to develop appropriate indicators, methodologies, and rules for sustainably harvesting marine resources. Complexities of scientific and financial factors often prevent addressing these, but new methodologies offer significant improvements on current and historical approaches. The Australian spanner crab fishery is used to demonstrate this. Between 1999 and 2006, an empirical management procedure using linear regression of fishery catch rates was used to set the annual total allowable catch (quota). A 6-year increasing trend in catch rates revealed shortcomings in the methodology, with a 68% increase in quota calculated for the 2007 fishing year. This large quota increase was prevented by management decision rules. A revised empirical management procedure was developed subsequently, and it achieved a better balance between responsiveness and stability. Simulations identified precautionary harvest and catch rate baselines to set quotas that ensured sustainable crab biomass and favourable performance for management and industry. The management procedure was simple to follow, cost-effective, robust to strong trends and changes in catch rates, and adaptable for use in many fisheries. Application of such “tried-and-tested” empirical systems will allow improved management of both data-limited and data-rich fisheries.

Evaluation of spatiotemporal imputations for fishing catch rate standardization

2017 ◽  
Vol 74 (9) ◽  
pp. 1348-1361
Author(s):  
Ross J. Marriott ◽  
Berwin A. Turlach ◽  
Kevin Murray ◽  
David V. Fairclough
Keyword(s):  
High Growth ◽  
Catch Rate ◽  
Commercial Fishing ◽  
Data Sets ◽  
Rate Data ◽  
Fishing Activity ◽  
Fish Stocks ◽  
Base Method ◽  
Catch Rates ◽  
Over Time

As commercial fishing activity shifts to target different grounds over time, spatial gaps can be created in catch rate data, leading to biases in derived indices of fish abundance. Imputation has been shown to reduce such biases. In this study, the relative performance of several imputation methods was assessed using simulated catch rate data sets. Simulations were carried out for three fish stocks targeted by a commercial hook-and-line fishery off the southwestern coast of Australia: snapper (Chrysophrys auratus), West Australian dhufish (Glaucosoma hebraicum), and baldchin groper (Choerodon rubescens). For high-growth scenarios, the mean squared errors (MSEs) of geometric and linear imputations were lower, indicating higher accuracy and precision than that for base method (constant value) imputations. For low-growth scenarios, the lowest MSEs were achieved for base method imputations. However, for the final standardized and imputed abundance indices, the base method index consistently demonstrated the largest biases. Our results demonstrate the importance of selecting an appropriate imputation method when standardizing catch rates from a commercial fishery that has changed its spatial pattern of fishing over time.

Accounting for marine reserves using spatial stock assessments

2015 ◽  
Vol 72 (2) ◽  
pp. 262-280 ◽  
Author(s):  
Carey R. McGilliard ◽  
André E. Punt ◽  
Richard D. Methot ◽  
Ray Hilborn
Keyword(s):  
Spatial Heterogeneity ◽  
Stock Assessment ◽  
Marine Reserves ◽  
Movement Patterns ◽  
Catch Rate ◽  
Fish Stock ◽  
Rate Data ◽  
Stock Assessments ◽  
Age Structured ◽  
Movement Parameters

Some fish stock assessments are conducted in regions that contain no-take marine reserves (NTMRs). NTMRs are expected to lead to spatial heterogeneity in fish biomass by allowing a buildup of biomass inside their borders while fishing pressure occurs outside. Stock assessments do not typically account for spatial heterogeneity caused by NTMRs, which may lead to biased estimates of biomass. Simulation modeling is used to analyze the ability of several stock assessment configurations to estimate current biomass after the implementation of a single, large NTMR. Age-structured spatial operating models with three patterns of ontogenetic movement are used to represent the “true” population dynamics. Results show that assessing populations as a single stock with use of fishery catch-rate data and without accounting for the NTMR results in severe underestimation of biomass for two of the movement patterns. Omitting fishery catch-rate data or allowing time-varying dome-shaped selectivity after NTMR implementation leads to improved estimates of current biomass, but severe bias in estimated trends in biomass over time. Performing separate assessments for fished areas and NTMRs leads to improved estimation performance in the absence of movement among assessment areas, but can severely overestimate biomass otherwise. Performing a spatial assessment with estimation of movement parameters among areas was found to be the best way to assess a species, even when movement patterns were unknown. However, future work should explore the performance of spatial assessments when catchability varies among areas.

Improving the catch efficiency of the West Coast rock lobster, Jasus lalandii

2000 ◽  
Vol 51 (6) ◽  
pp. 613 ◽  
Author(s):  
D. Loewenthal ◽  
S. Mayfield ◽  
G. M. Branch
Keyword(s):  
Weight Loss ◽  
South African ◽  
West Coast ◽  
Capture Rate ◽  
Catch Rate ◽  
Rock Lobster ◽  
The South ◽  
The West ◽  
The Relationship

The South African commercial rock-lobster industry employs an average soak time of 22 h for traps. Experiments were undertaken to test (1) the rate of bait loss with soak time and the effect that protection of the bait has on bait loss, (2) the relationship between catch rate (numbers per trap) and soak time for traps with either protected or unprotected bait, and (3) the effect of two bait types (whole maasbanker and hake heads) on the catch of rock lobsters. There were substantial losses of unprotected bait within 6 h; substantially less weight loss was observed from protected bait even after a 48-h soak time. The numbers of rock lobsters caught in traps with unprotected bait were low relative to the capture rate with protected bait. The highest capture rate occurred after 6 h for unprotected bait and 6–12 h for protected bait. There was no significant effect of bait type (maasbanker v. hake heads) on the number or size of rock lobsters. To optimize catch efficiency, the commercial industry should use protected bait and soak times as short as 6–12 h.

Using Bayesian geostatistical models to correct gridded hydrological products relative to the actually observed streamflow

2020 ◽  
Author(s):  
Thea Roksvåg ◽  
Ingelin Steinsland ◽  
Kolbjørn Engeland
Keyword(s):  
Linear Relationship ◽  
Gaussian Random Field ◽  
Annual Runoff ◽  
Flow Index ◽  
Geostatistical Model ◽  
Ungauged Catchments ◽  
Geostatistical Methods ◽  
Catchment Areas ◽  
Geostatistical Models ◽  
Input Variables

<p>Conceptual hydrological models are process-based models that are used to simulate flow indices based on physical or empirical relationships and input variables like precipitation, temperature and land use. For many applications the goal is to use the process-based model to construct a gridded map of the flow index of interest, e.g. for mean annual runoff. However, one challenge is that the resulting runoff map does not necessarily fit to the actually observed streamflow data when the grid nodes are aggregated to catchment areas. A solution to this problem is to correct the gridded hydrological product afterwards relative to the actually observed streamflow in areas where we have measurements. In this work, we explore different Bayesian geostatistical tools that can contribute to this correction. We suggest a model where the  observed streamflow is used as a response variable and the gridded hydrological product is used as a covariate. In particular, a geostatistical model with a spatially varying coefficient (SVC) is suggested, and we develop a linear relationship between the response and the covariate that is allowed to vary in the study area. This is achieved by modeling the regression coefficient as a Gaussian random field (GRF) that defines the spatial pattern of the linear relationship. We also test two simpler geostatistical models, and investigate how short records of runoff can be included in the correction procedure. </p><p>The geostatistical models are tested by correcting a gridded mean annual runoff product from the HBV model relative to the observed  mean annual runoff. We use data from around 400 catchments in Norway from 1981-2010. The results show that all three geostatistical methods lead to a considerably better fit between the corrected product and the actually observed streamflow for the gauged catchments, which was our main goal. In addition, we also obtain improved predictions for many of the ungauged catchments in Norway.</p>

Using logbook‐based catch‐rate data to detect yellow eel population trends in the southern Baltic Sea

2021 ◽  
Author(s):  
Malte Dorow ◽  
Wolf‐Christian Lewin ◽  
Dietmar Lill ◽  
Claus Ubl ◽  
Jens Frankowski
Keyword(s):  
Baltic Sea ◽  
Catch Rate ◽  
Population Trends ◽  
Rate Data ◽  
Southern Baltic Sea ◽  
Yellow Eel ◽  
Southern Baltic

Integrating imputation and standardization of catch rate data in the calculation of relative abundance indices

2011 ◽  
Vol 109 (1) ◽  
pp. 157-167 ◽  
Author(s):  
Thomas R. Carruthers ◽  
Robert N.M. Ahrens ◽  
Murdoch K. McAllister ◽  
Carl J. Walters
Keyword(s):  
Relative Abundance ◽  
Catch Rate ◽  
Rate Data ◽  
Abundance Indices

scholarly journals LOG-VEROSSIMILHANÇA COMBINADA PARA COMPARAÇÃO DE ESTRUTURAS DE CONTINUIDADE ESPACIAL EM FLORESTA ESTACIONAL DECIDUAL

FLORESTA ◽  
2015 ◽  
Vol 45 (4) ◽  
pp. 797
Author(s):  
Julio Cesar Wojciechowski ◽  
Julio Eduardo Arce ◽  
Saulo Henrique Weber ◽  
Paulo Justiniano Ribeiro Júnior ◽  
Carlos Alberto da Fonseca Pires
Keyword(s):  
Spatial Dependence ◽  
Deciduous Forest ◽  
Geostatistical Model ◽  
Post Intervention ◽  
Spatial Continuity ◽  
Log Likelihood ◽  
Geostatistical Models ◽  
Akaike Criterion ◽  
Spatial Volume ◽  
Fragmented Forests

O presente estudo teve como objetivo verificar a dependência espacial e distribuição do volume em três fragmentos de Floresta Estacional Decidual, geograficamente separados e com idades pós-intervenção distintas, utilizando um modelo geoestatístico único ou combinado. Os dados foram coletados em 56 unidades amostrais de 250 m2, distribuídas sistematicamente em uma malha de 40 x 40 m, onde foram medidos os indivíduos com DAP ≥ 10 cm a partir do centro da unidade conforme metodologia descrita por Prodan. Os dados foram submetidos a dois tipos de análise, sendo o primeiro um ajuste individual das áreas a título de comparação entre seus modelos e o segundo, um ajuste proposto pelo método combinado, ambos utilizando modelos geoestatísticos, com ajuste pela função da maximização do logaritmo da verossimilhança. Os modelos foram comparados pelo critério de informação de Akaike (AIC) e a relação do parâmetro alcance como indicação do grau de dependência espacial. Os resultados mostram que os modelos combinados foram superiores em relação aos ajustes dos modelos para as áreas individuais. Indica-se a aplicação de modelos geoestatísticos de log-verossimilhança combinados em formações florestais fragmentadas para uma melhor análise e detecção da estrutura de correlação espacial do volume. AbstractCombined log-likelihood for comparison of spatial continuity structures in deciduous forest. The present study aimed to examine spatial dependence and distribution of volume in three fragments of Subtropical forest, geographically separated and the different post-intervention ages, using a single geostatistical model or combined model. Data were collected from 56 sampling units of 250 m2 systematically distributed in a grid of 40 x 40 m. Trees with DBH ≥ 10 cm were measured according to Prodan’s methodology. Two types of analysis were applied to the data. The first one was an individual adjustment for comparison between their models and the second one consisted in the proposed combined approach adjustment. Both analysis used geostatistical models with adjustment function maximizing log-likelihood. Models were compared using Akaike criterion (AIC) and relational range parameter as an indication of spatial dependence degree. Results show that combined models had lower AIC values as well as greater spatial dependence degree on adjustments of individual areas models. This research indicates the use of combined log-likelihood geostatistical models to study fragmented forests for analysis and detection of spatial volume correlation structure.Keywords: Geostatistics; forest inventory; mixed models; Akaike criterion.

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