General state-space population dynamics model for Bayesian stock assessment

Research output: Contribution to journalArticle

Researchers

  • Samu H.P. Mantyniemi
  • Rebecca E. Whitlock
  • Tommi A. Perala
  • Paul Blomstedt

  • Jarno P. Vanhatalo
  • Margarita Maria Rincon
  • Anna K. Kuparinen
  • Henni P. Pulkkinen
  • O. Sakari Kuikka

Research units

  • University of Helsinki
  • Swedish University of Agricultural Sciences
  • ICMAN-CSIC
  • Luke Natural Resources Institute Finland

Abstract

This study presents a state-space modelling framework for the purposes of stock assessment. The stochastic population dynamics build on the notion of correlated survival and capture events among individuals. The correlation is thought to arise as a combination of schooling behaviour, a spatially patchy environment, and common but unobserved environmental factors affecting all the individuals. The population dynamics model isolates the key biological processes, so that they are not condensed into one parameter but are kept separate. This approach is chosen to aid the inclusion of biological knowledge from sources other than the assessment data at hand. The model can be tailored to each case by choosing appropriate models for the biological processes. Uncertainty about the model parameters and about the appropriate model structures is then described using prior distributions. Different combinations of, for example, age, size, phenotype, life stage, species, and spatial location can be used to structure the population. To update the prior knowledge, the model can be fitted to data by defining appropriate observation models. Much like the biological parameters, the observation models must also be tailored to fit each individual case.

Details

Original languageEnglish
Pages (from-to)2209-2222
Number of pages14
JournalICES Journal of Marine Science
Volume72
Issue number8
Publication statusPublished - 2015
MoE publication typeA1 Journal article-refereed

    Research areas

  • Dirichlet-Multinomial distribution, Effective population size, Markov chain Monte Carlo, Stock assessment, Uncertainty

ID: 17188175