Computational Model Library

FishCensus (1.1.0)

Context

Underwater visual census (UVC) methods are used worldwide to monitor shallow marine and freshwater habitats and support management and conservation decisions. However, several sources of bias still undermine the ability of these methods to accurately estimate abundances of some species.

FishCensus Model

FishCensus is an agent-based model that simulates underwater visual census of fish populations, a method used worldwide to survey shallow marine and freshwater habitats that involves a diver counting fish species to estimate their density. It can help estimate sampling bias, apply correction factors to field surveys and decide on the best method to survey a particular species, given its behavioural traits, detectability or speed.
A modified vector-based boids-like movement submodel is used for fish, and complex behaviours such as schooling or diver avoidance / attraction can be represented.

How it works

The FishCensus model comes with two separate programs. The Species Creator is used to create new fish species or observe/edit existing ones. Species parameters can be exported as a .csv file and imported into the main model where the simulation happens.

A virtual diver uses a survey method to estimate fish density. The true density of fish is known, which allows for the quantification of bias, a measure that is very difficult to determine in the field.

For more info and tutorials, visit the wiki on Bitbucket.

If you use this model, please cite the original publication.

FishCensus.png

Release Notes

Model version 1.1. Added some new sliders to control globals, initial movement stabilisation now uses the FIRST behaviour in the list for all individuals instead of a random one. For species with very different behaviours this can lead to faster stabilisation of movement patterns before sampling.

Associated Publications

Pais MP, Cabral HN, 2018. Effect of underwater visual survey methodology on bias and precision of fish counts: a simulation approach. PeerJ 6:e5378 https://doi.org/10.7717/peerj.5378

Pais MP, Cabral HN, 2017. Fish behaviour effects on the accuracy and precision of underwater visual census surveys. A virtual ecologist approach using an individual-based model. Ecological Modelling 346, 58-69. https://doi.org/10.1016/j.ecolmodel.2016.12.011

This release is out-of-date. The latest version is 2.0.0

FishCensus 1.1.0

Context

Underwater visual census (UVC) methods are used worldwide to monitor shallow marine and freshwater habitats and support management and conservation decisions. However, several sources of bias still undermine the ability of these methods to accurately estimate abundances of some species.

FishCensus Model

FishCensus is an agent-based model that simulates underwater visual census of fish populations, a method used worldwide to survey shallow marine and freshwater habitats that involves a diver counting fish species to estimate their density. It can help estimate sampling bias, apply correction factors to field surveys and decide on the best method to survey a particular species, given its behavioural traits, detectability or speed.
A modified vector-based boids-like movement submodel is used for fish, and complex behaviours such as schooling or diver avoidance / attraction can be represented.

How it works

The FishCensus model comes with two separate programs. The Species Creator is used to create new fish species or observe/edit existing ones. Species parameters can be exported as a .csv file and imported into the main model where the simulation happens.

A virtual diver uses a survey method to estimate fish density. The true density of fish is known, which allows for the quantification of bias, a measure that is very difficult to determine in the field.

For more info and tutorials, visit the wiki on Bitbucket.

If you use this model, please cite the original publication.

Release Notes

Model version 1.1. Added some new sliders to control globals, initial movement stabilisation now uses the FIRST behaviour in the list for all individuals instead of a random one. For species with very different behaviours this can lead to faster stabilisation of movement patterns before sampling.

Version Submitter First published Last modified Status
2.0.0 Miguel Pais Thu Feb 9 11:45:23 2017 Tue Jun 25 14:36:16 2024 Published
1.1.0 Miguel Pais Tue Jan 3 22:21:59 2017 Mon Mar 12 21:51:48 2018 Published Peer Reviewed
1.0.0 Miguel Pais Tue Dec 6 17:39:57 2016 Fri Mar 2 23:49:43 2018 Published

Discussion

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