Use of computer vision onboard fishing vessels to quantify catches: The iObserver

Abstract Monitoring plays a key role in all aspects of fisheries management, including those related to sustainable management of resources, the economic performance of the fishery, and the distribution of benefits from the exploitation of the fishery and environment. In this manuscript, an electronic device (the iObserver) is described, which aims to improve fisheries monitoring by identifying and quantifying fishing catches on board commercial vessels. This device is located over the conveyor belt in the fishing sorting area to automatically take pictures of the entire catch during fish separation. Each picture is analyzed using open source image recognition software to identify the number of individuals, the species and length of each individual based on skin descriptors (color, texture), and shape. The iObserver is equipped with a graphical and user-friendly interface. The information provided by the iObserver is sent to the RedBox software, where it is aggregated and augmented with vessel instrumentation data, such as location, velocity, and course. Then, the data are sent to a shore-based center to be used for different purposes, including the following: feeding mathematical models describing stock evolution; identifying those regions with a large presence of individuals below a Minimum Conservation Reference Size (MCRS); and supporting administrative decisions about a given fishing region.

[1]  Jørgen Dalskov,et al.  Fully documented fishery: a tool to support a catch quota management system , 2011 .

[2]  Anil K. Jain Fundamentals of Digital Image Processing , 2018, Control of Color Imaging Systems.

[3]  Jónas R. Viðarsson,et al.  Tools and Technologies for the Monitoring, Control and Surveillance of Unwanted Catches , 2018, The European Landing Obligation.

[4]  Rafael C. González,et al.  Digital image processing using MATLAB , 2006 .

[5]  A. Moreno,et al.  Integration of fishery-dependent data sources in support of octopus spatial management , 2014 .

[6]  Karim Erzini,et al.  Weight-length relationships for selected fish species of the small-scale demersal fisheries of the south and south-west coast of Portugal , 1997 .

[7]  Jorge Stolfi,et al.  T-HOG: An effective gradient-based descriptor for single line text regions , 2013, Pattern Recognit..

[8]  T. Emery,et al.  Changes in logbook reporting by commercial fishers following the implementation of electronic monitoring in Australian Commonwealth fisheries , 2019, Marine Policy.

[9]  Gerhard Rigoll,et al.  Comparison of confidence measures for face recognition , 2000, Proceedings Fourth IEEE International Conference on Automatic Face and Gesture Recognition (Cat. No. PR00580).

[10]  D. Conesa,et al.  Integrating fishing spatial patterns and strategies to improve high seas fisheries management , 2018, Marine Policy.

[11]  Maria Grazia Pennino,et al.  Discard management: A spatial multi-criteria approach , 2017 .

[12]  J. Daugman Two-dimensional spectral analysis of cortical receptive field profiles , 1980, Vision Research.

[13]  I. Sobrino,et al.  Length-weight relationships of 76 fish species from the Gulf of Cadiz (SW Spain) , 2012 .

[14]  Gunther Wyszecki,et al.  Color Science: Concepts and Methods, Quantitative Data and Formulae, 2nd Edition , 2000 .

[15]  Daoliang Li,et al.  The Measurement of Fish Size by Machine Vision - A Review , 2015, CCTA.

[16]  Lars O. Mortensen,et al.  Remote electronic monitoring and the landing obligation – some insights into fishers’ and fishery inspectors’ opinions , 2017 .

[17]  C. Ulrich,et al.  Discarding of cod in the Danish Fully Documented Fisheries trials , 2015 .