How to estimate scavenger fish abundance using baited camera data

Baited cameras are often used for abundance estimation wherever alternative techniques are precluded, e.g. in abyssal systems and areas such as reefs. This method has thus far used models of the arrival process that are deterministic and, therefore, permit no estimate of precision. Furthermore, erro...

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Bibliographic Details
Published in:Marine ecology. Progress series (Halstenbek) 2007-11, Vol.350, p.223-234
Main Authors: Farnsworth, K. D., Thygesen, U. H., Ditlevsen, S., King, N. J.
Format: Article
Language:English
Subjects:
Fish
Fish scales
Fishing lines
Marine
Modeling
Odors
Pisces
Plumes
Stochastic models
Swimming
THEME SECTION: Role of scavengers in marine ecosystems
Time series
Time series models
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Summary:Baited cameras are often used for abundance estimation wherever alternative techniques are precluded, e.g. in abyssal systems and areas such as reefs. This method has thus far used models of the arrival process that are deterministic and, therefore, permit no estimate of precision. Furthermore, errors due to multiple counting of fish and missing those not seen by the camera have restricted the technique to using only the time of first arrival, leaving a lot of data redundant. Here, we reformulate the arrival process using a stochastic model, which allows the precision of abundance estimates to be quantified. Assuming a non-gregarious, cross-current-scavenging fish, we show that prediction of abundance from first arrival time is extremely uncertain. Using example data, we show that simple regression-based prediction from the initial (rising) slope of numbers at the bait gives good precision, accepting certain assumptions. The most precise abundance estimates were obtained by including the declining phase of the time series, using a simple model of departures, and taking account of scavengers beyond the camera’s view, using a hidden Markov model.
ISSN:0171-8630
1616-1599
DOI:10.3354/meps07190