Secretariat of the Pacific Community / Secrétariat de la Communauté du Pacifique (SPC)

OCEANIC FISHERIES PROGRAMME / PROGRAMME PECHE HAUTURIERE
OFP Home News Staff / Personnel Member Countries / Pays Membres OFP Meetings Jobs / Emplois Links / Liens
WCPFC WCPFC news WCPFC Scientific Committee / Comité Scientifique SCTB SPC

 


Statistics and Monitoring
Statistiques des Pêcheries Thonières

Overview
In-Country Area
Tuna Fishery Data Catalogue

Regional Data Forms

Coverage & Quality of Data


Tuna Ecology and Biology
Ecologie et Biologie du Thon
Tuna Biology and Behaviour
Environmental Relationship & Modelling
Billfish & By-catch
Ecosystem Research
Tuna Tagging


Stock Assessement and Modelling
Evaluation des Stocks & Modélisation
Stock Assessment


Publications and Articles
Publications et Articles
Statistics Publications
Research Publications
Technical Reports
Donors Reports
Other Reports
DIGITAL LIBRARY

| Disclaimer | Contact OFP |
 English       Site en Français

 

Secretariat of the Pacific Community
BP D5, 98848 Noumea
NEW CALEDONIA

Ph +687 262000 - Fx +687 263818 
Email: oceanfishATspc.int
 


 wpe2.jpg (7712 bytes)

A spatial population dynamics simulation model of tropical tunas using a habitat index based on environmental parameters

Bertignac M., Lehodey P., Hampton J. (1998). A spatial population dynamics simulation model of tropical tunas using a habitat index based on environmental parameters. Fisheries Oceanography (special issue of GLOBEC Open Science Meeting), Volume 7, number 3 and 4: 326 - 334


[Please send me a copy of the full article]

Abstract. We are developing a spatial, multi-gear, multi-species population dynamics simulation model for tropical tunas in the Pacific Ocean. The model is age-structured to account for growth and gear selectivity. It includes a tuna movement model based on a diffusion-advection equation in which the advective term is proportional to the gradient of a habitat index. The monthly geographical distribution of recruitment is defined by assuming that spawning occurs in areas where sea surface temperature is above 25° C. During the first three months of their life, simulated tunas are transported by oceanic currents, after which movement is conditioned by gradients in the habitat index. Independent estimates of natural mortality rates and population size from large-scale tagging experiments carried out by the Secretariat of the Pacific Community are used in the simulations. The habitat index consists of components due to forage density and sea surface temperature, both of which are suspected to play major roles in determining tuna distribution. Since direct observations of forage are not available on a basin scale, we developed a sub-model to simulate the surface tuna forage production (Lehodey et al. 1998). Presently, only skipjack (Katsuwonus pelamis; a surface tuna species caught by purse-seine and pole-and-line) is considered, at a one-degree square resolution and on a monthly climatological time-series. Despite the simplicity of the model and the limitations of the data used, the simulation model is able to predict a distribution of skipjack catch rates of the different fleets involved in the fishery, which is fairly consistent with observations.