Linking effort and fishing mortality in a mixed fisheries model: comparing linear versus non-linear assumptions

Publikation: Bidrag til tidsskriftTidsskriftartikelfagfællebedømt

Standard

Linking effort and fishing mortality in a mixed fisheries model : comparing linear versus non-linear assumptions. / Thøgersen, Thomas Talund; Hoff, Ayoe; Frost, Hans Staby.

I: Fisheries Research, Bind 127-128, 2012, s. 9–17.

Publikation: Bidrag til tidsskriftTidsskriftartikelfagfællebedømt

Harvard

Thøgersen, TT, Hoff, A & Frost, HS 2012, 'Linking effort and fishing mortality in a mixed fisheries model: comparing linear versus non-linear assumptions', Fisheries Research, bind 127-128, s. 9–17. https://doi.org/10.1016/j.fishres.2012.04.015

APA

Thøgersen, T. T., Hoff, A., & Frost, H. S. (2012). Linking effort and fishing mortality in a mixed fisheries model: comparing linear versus non-linear assumptions. Fisheries Research, 127-128, 9–17. https://doi.org/10.1016/j.fishres.2012.04.015

Vancouver

Thøgersen TT, Hoff A, Frost HS. Linking effort and fishing mortality in a mixed fisheries model: comparing linear versus non-linear assumptions. Fisheries Research. 2012;127-128:9–17. https://doi.org/10.1016/j.fishres.2012.04.015

Author

Thøgersen, Thomas Talund ; Hoff, Ayoe ; Frost, Hans Staby. / Linking effort and fishing mortality in a mixed fisheries model : comparing linear versus non-linear assumptions. I: Fisheries Research. 2012 ; Bind 127-128. s. 9–17.

Bibtex

@article{57f870c58d07497da30f95453fc3f0a2,
title = "Linking effort and fishing mortality in a mixed fisheries model: comparing linear versus non-linear assumptions",
abstract = "Since the implementation of the Common Fisheries Policy of the European Union in 1983, the management of EU fisheries has been enormously challenging. The abundance of many fish stocks has declined because too much fishing capacity has been utilised on healthy fish stocks. Today, this decline in fish stocks has led to overcapacity in many fisheries, leading to incentives for overfishing. Recent research has shown that the allocation of effort among fleets can play an important role in mitigating overfishing when the targeting covers a range of species (multi-species—i.e., so-called mixed fisheries), while simultaneously optimising the overall economic performance of the fleets. The so-called FcubEcon model, in particular, has elucidated both the biologically and economically optimal method for allocating catches—and thus effort—between fishing fleets, while ensuring that the quotas are not exceeded. Until now, the FcubEcon modelling approach has assumed that there is a simplified linear relationship between effort and fishing mortality. The present study introduces an extension of the FcubEcon model, the so-called SOMER model, that allows this relationship to be non-linear by linking the biological catch equation with the economic production function. Furthermore, the SOMER model relaxes the assumption of the joint production of fishing metiers, unique and separately defined sub-fleets, to allow for more detail regarding the flexibility to target specific groups of species. Thereby, the SOMER model enables the managers to assess the alternative management scenarios more accurately than the existing models.",
author = "Th{\o}gersen, {Thomas Talund} and Ayoe Hoff and Frost, {Hans Staby}",
year = "2012",
doi = "10.1016/j.fishres.2012.04.015",
language = "English",
volume = "127-128",
pages = "9–17",
journal = "Fisheries Research",
issn = "0165-7836",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Linking effort and fishing mortality in a mixed fisheries model

T2 - comparing linear versus non-linear assumptions

AU - Thøgersen, Thomas Talund

AU - Hoff, Ayoe

AU - Frost, Hans Staby

PY - 2012

Y1 - 2012

N2 - Since the implementation of the Common Fisheries Policy of the European Union in 1983, the management of EU fisheries has been enormously challenging. The abundance of many fish stocks has declined because too much fishing capacity has been utilised on healthy fish stocks. Today, this decline in fish stocks has led to overcapacity in many fisheries, leading to incentives for overfishing. Recent research has shown that the allocation of effort among fleets can play an important role in mitigating overfishing when the targeting covers a range of species (multi-species—i.e., so-called mixed fisheries), while simultaneously optimising the overall economic performance of the fleets. The so-called FcubEcon model, in particular, has elucidated both the biologically and economically optimal method for allocating catches—and thus effort—between fishing fleets, while ensuring that the quotas are not exceeded. Until now, the FcubEcon modelling approach has assumed that there is a simplified linear relationship between effort and fishing mortality. The present study introduces an extension of the FcubEcon model, the so-called SOMER model, that allows this relationship to be non-linear by linking the biological catch equation with the economic production function. Furthermore, the SOMER model relaxes the assumption of the joint production of fishing metiers, unique and separately defined sub-fleets, to allow for more detail regarding the flexibility to target specific groups of species. Thereby, the SOMER model enables the managers to assess the alternative management scenarios more accurately than the existing models.

AB - Since the implementation of the Common Fisheries Policy of the European Union in 1983, the management of EU fisheries has been enormously challenging. The abundance of many fish stocks has declined because too much fishing capacity has been utilised on healthy fish stocks. Today, this decline in fish stocks has led to overcapacity in many fisheries, leading to incentives for overfishing. Recent research has shown that the allocation of effort among fleets can play an important role in mitigating overfishing when the targeting covers a range of species (multi-species—i.e., so-called mixed fisheries), while simultaneously optimising the overall economic performance of the fleets. The so-called FcubEcon model, in particular, has elucidated both the biologically and economically optimal method for allocating catches—and thus effort—between fishing fleets, while ensuring that the quotas are not exceeded. Until now, the FcubEcon modelling approach has assumed that there is a simplified linear relationship between effort and fishing mortality. The present study introduces an extension of the FcubEcon model, the so-called SOMER model, that allows this relationship to be non-linear by linking the biological catch equation with the economic production function. Furthermore, the SOMER model relaxes the assumption of the joint production of fishing metiers, unique and separately defined sub-fleets, to allow for more detail regarding the flexibility to target specific groups of species. Thereby, the SOMER model enables the managers to assess the alternative management scenarios more accurately than the existing models.

U2 - 10.1016/j.fishres.2012.04.015

DO - 10.1016/j.fishres.2012.04.015

M3 - Journal article

VL - 127-128

SP - 9

EP - 17

JO - Fisheries Research

JF - Fisheries Research

SN - 0165-7836

ER -

ID: 38341409