Model-based calibration of gear-specific fish abundance survey data as a change-of-support problem

In a continental-scale fish abundance study, a major challenge in deriving an absolute abundance estimate lies in the fact that regional surveys deploy different gear types, each with its unique field of view, producing gear-specific relative abundance data. Thus, data from regional surveys in the study must be converted from the gear-specific relative scale to an absolute scale before being combined to estimate a continental scale absolute abundance. In this paper, we develop a tool that takes gear-based data as input, and produces as output the required conversion, with associated uncertainty. Methodologically, this tool is operationalized from a Bayesian hierarchical model which we develop in an inferential context that is akin to the change-of-support problem often encountered in spatial studies; the actual context here is to reconcile abundance data at various gear-specific scales, some being relative, and others, absolute. We consider data from a small-scale calibration experiment in which 2 to 4 underwater video camera types, as well as an acoustic echosounder, were simultaneously deployed on each of 21 boat trips. While acoustic fish signals are recorded along transects on the absolute scale, they are subject to confounding from acoustically similar species, thus requiring an externally derived correction factor. Conversely, a camera allows visual distinction between species but records data on a gear-specific relative scale. Our statistical modeling framework reflects the relationship among all 5 gear types across the 21 trips, and the resulting model is used to derive calibration formulae to translate relative abundance data to the corrected absolute abundance scale whenever a camera is deployed alone. Cross-validation is conducted using mark-recapture abundance estimates. We also briefly discuss the case when one camera type is deployed alongside the echosounder.