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Semiparametric Copula Estimation for Spatially Correlated Multivariate Mixed Outcomes: Analyzing Visual Sightings of Fin Whales from a Line Transect Survey

Tomotaka Momozaki, Tomoyuki Nakagawa, Shonosuke Sugasawa, Hiroko Kato Solvang

Abstract

For marine biologists, ascertaining the dependence structures between marine species and marine environments, such as sea surface temperature and ocean depth, is imperative for defining ecosystem functioning and providing insights into the dynamics of marine ecosystems. However, obtained data include not only continuous but also discrete data, such as binaries and counts (referred to as mixed outcomes), as well as spatial correlations, both of which make conventional multivariate analysis tools impractical. To solve this issue, we propose semiparametric Bayesian inference and develop an efficient algorithm for computing the posterior of the dependence structure based on the rank likelihood under a latent multivariate spatial Gaussian process using the Markov chain Monte Carlo method. To alleviate the computational intractability caused by the Gaussian process, we also provide a scalable implementation that leverages the nearest-neighbor Gaussian process. Extensive numerical experiments reveal that the proposed method reliably infers the dependence structures of spatially correlated mixed outcomes. Finally, we apply the proposed method to a dataset collected during an international synoptic krill survey in the Scotia Sea of the Antarctic Peninsula to infer the dependence structure between fin whales (Balaenoptera physalus), krill biomass, and relevant oceanographic data.

Semiparametric Copula Estimation for Spatially Correlated Multivariate Mixed Outcomes: Analyzing Visual Sightings of Fin Whales from a Line Transect Survey

Abstract

For marine biologists, ascertaining the dependence structures between marine species and marine environments, such as sea surface temperature and ocean depth, is imperative for defining ecosystem functioning and providing insights into the dynamics of marine ecosystems. However, obtained data include not only continuous but also discrete data, such as binaries and counts (referred to as mixed outcomes), as well as spatial correlations, both of which make conventional multivariate analysis tools impractical. To solve this issue, we propose semiparametric Bayesian inference and develop an efficient algorithm for computing the posterior of the dependence structure based on the rank likelihood under a latent multivariate spatial Gaussian process using the Markov chain Monte Carlo method. To alleviate the computational intractability caused by the Gaussian process, we also provide a scalable implementation that leverages the nearest-neighbor Gaussian process. Extensive numerical experiments reveal that the proposed method reliably infers the dependence structures of spatially correlated mixed outcomes. Finally, we apply the proposed method to a dataset collected during an international synoptic krill survey in the Scotia Sea of the Antarctic Peninsula to infer the dependence structure between fin whales (Balaenoptera physalus), krill biomass, and relevant oceanographic data.
Paper Structure (21 sections, 17 equations, 28 figures, 104 tables)

This paper contains 21 sections, 17 equations, 28 figures, 104 tables.

Table of Contents

  1. Introduction
  2. Background and motivation
  3. Motivating application: Fin whale sighting data
  4. Extended rank likelihood for semiparametric copula estimation
  5. Copula estimation under spatial correlation
  6. Latent models with spatial correlation
  7. Posterior computation
  8. Scalable posterior computation under large spatial data
  9. Simulation study
  10. Application to fin whale sighting data
  11. Discussion
  12. Additional Simulation Studies
  13. Sensitivity to Number of Neighbors $m$ in spBGCNNGP
  14. Simulation with Real Data Spatial Locations
  15. Sensitivity to Correlation Function Specification
  16. ...and 6 more sections

Figures (28)

  • Figure 1: The 95% credible interval and the posterior median of each correlation coefficient by hoff2007extending's (BGC) and our proposed methods (spBGC): Cross marks denote true values.
  • Figure 2: Spatial distribution of the six variables in the fin whale sighting dataset: krill biomass (Krill), fin whale sightings (Whale), sea surface temperature (SST), water depth (Depth), slope of the depth (Slope), and gradient of surface temperature (SST.grd). Brighter/darker colors for SST and Depth indicate higher/lower temperatures and shallower/deeper water depths, respectively.
  • Figure 9: The logarithm of the MSEs for $p=6$ (left) and $p=9$ (right)
  • Figure 10: The CPs for $p=6$ (left) and $p=9$ (right)
  • Figure 11: The ALs for $p=6$ (left) and $p=9$ (right)
  • ...and 23 more figures