TY - JOUR
T1 - New developments in the analysis of catch time series as the basis for fish stock assessments
T2 - The CMSY++ method
AU - Froese, Rainer
AU - Winker, Henning
AU - Coro, Gianpaolo
AU - Palomares, Maria Lourdes Deng
AU - Tsikliras, Athanassios C.
AU - Dimarchopoulou, Donna
AU - Touloumis, Konstantinos
AU - Demirel, Nazli
AU - Vianna, Gabriel M.S.
AU - Scarcella, Giuseppe
AU - Schijns, Rebecca
AU - Liang, Cui
AU - Pauly, Daniel
N1 - Funding Information:
Rainer Froese acknowledges support by the German Federal Nature Conservation Agency (BfN); Maria-Lourdes D Palomares and Daniel Pauly acknowledge support from the Sea Around Us, itself funded by a number of philanthropic foundations, notably the Minderoo Foundation, which underwrote the work leading to the update of the reconstructed catches to 2018 and the majority of the CMSY++ assessments in the global map shown as Fig. 3. We also thank Nicolas Bailly and Elizabeth Bato David for their assistance in creating this map. Athanas-sios C Tsikliras was partly supported by the European Union’s Horizon 2020 Research and Innovation Program (H2020-BG-10-2020-2), grant number No 101000302— EcoScope (Ecocentric management for sustainable fisheries and healthy marine ecosystems). The article reflects only the authors’ view and the Commission is not responsible for any use that may be made of the information it contains.
Publisher Copyright:
© 2023, Pensoft Publishers. All rights reserved.
PY - 2023/10/30
Y1 - 2023/10/30
N2 - Following an introduction to the nature of fisheries catches and their information content, a new development of CMSY, a data-lim-ited stock assessment method for fishes and invertebrates, is presented. This new version, CMSY++, overcomes several of the deficiencies of CMSY, which itself improved upon the “Catch-MSY” method published by S. Martell and R. Froese in 2013. The catch-only application of CMSY++ uses a Bayesian implementation of a modified Schaefer model, which also allows the fitting of abundance indices should such information be available. In the absence of historical catch time series and abundance indices, CMSY++ depends strongly on the provision of appropriate and informative priors for plausible ranges of initial and final stock depletion. An Artificial Neural Network (ANN) now assists in selecting objective priors for relative stock size based on patterns in 400 catch time series used for training. Regarding the cross-validation of the ANN predictions, of the 400 real stocks used in the training of ANN, 94% of final relative biomass (B/k) Bayesian (BSM) estimates were within the approximate 95% confidence limits of the respective CMSY++ estimate. Also, the equilibrium catch-biomass relations of the modified Schaefer model are compared with those of alternative surplus-production and age-structured models, suggesting that the latter two can be strongly biased towards underestimating the biomass required to sustain catches at low abundance. Numerous independent applications demonstrate how CMSY++ can incorporate, in addition to the required catch time series, both abundance data and a wide variety of ancillary information. We stress, however, the caveats and pitfalls of naively using the built-in prior options, which should instead be evaluated case-by-case and ideally be replaced by independent prior knowledge.
AB - Following an introduction to the nature of fisheries catches and their information content, a new development of CMSY, a data-lim-ited stock assessment method for fishes and invertebrates, is presented. This new version, CMSY++, overcomes several of the deficiencies of CMSY, which itself improved upon the “Catch-MSY” method published by S. Martell and R. Froese in 2013. The catch-only application of CMSY++ uses a Bayesian implementation of a modified Schaefer model, which also allows the fitting of abundance indices should such information be available. In the absence of historical catch time series and abundance indices, CMSY++ depends strongly on the provision of appropriate and informative priors for plausible ranges of initial and final stock depletion. An Artificial Neural Network (ANN) now assists in selecting objective priors for relative stock size based on patterns in 400 catch time series used for training. Regarding the cross-validation of the ANN predictions, of the 400 real stocks used in the training of ANN, 94% of final relative biomass (B/k) Bayesian (BSM) estimates were within the approximate 95% confidence limits of the respective CMSY++ estimate. Also, the equilibrium catch-biomass relations of the modified Schaefer model are compared with those of alternative surplus-production and age-structured models, suggesting that the latter two can be strongly biased towards underestimating the biomass required to sustain catches at low abundance. Numerous independent applications demonstrate how CMSY++ can incorporate, in addition to the required catch time series, both abundance data and a wide variety of ancillary information. We stress, however, the caveats and pitfalls of naively using the built-in prior options, which should instead be evaluated case-by-case and ideally be replaced by independent prior knowledge.
KW - data limited stock assessments
KW - Elasmobranchii
KW - finfish
KW - global fisheries
KW - informative priors
KW - shellfish
KW - stock status
KW - Teleostei
UR - http://www.scopus.com/inward/record.url?scp=85175563469&partnerID=8YFLogxK
U2 - 10.3897/aiep.53.e105910
DO - 10.3897/aiep.53.e105910
M3 - Article
AN - SCOPUS:85175563469
SN - 0137-1592
VL - 2023
SP - 173
EP - 189
JO - Acta Ichthyologica et Piscatoria
JF - Acta Ichthyologica et Piscatoria
IS - 53
ER -