Abstract
Noninvasive morphological feature monitoring is essential in fish culture, since these features are currently measured manually with a high cost. These morphological parameters can concern the size or mass of the fish, or its health as indicated, for example, by the color of the eyes or the gills. Several approaches have been proposed, based either on image processing or machine learning techniques. In this paper, both of these approaches have been combined in a unified environment with novel techniques (e.g., edge or corner detection and pattern stretching) to estimate the fish’s relative length, height and the area it occupies in the image. The method can be extended to estimate the absolute dimensions if a pair of cameras is used for obscured or slanted fish. Moreover, important fish parts such as the caudal, spiny and soft dorsal, pelvic and anal fins are located. Four species popular in fish cultures have been studied: Dicentrarchus labrax (sea bass), Diplodus puntazzo, Merluccius merluccius (cod fish) and Sparus aurata (sea bream). Taking into consideration that there are no large public datasets for the specific species, the training and testing of the developed methods has been performed using 25 photographs per species. The fish length estimation error ranges between 1.9% and 13.2%, which is comparable to the referenced approaches that are trained with much larger datasets and do not offer the full functionality of the proposed method.
Highlights
Various fish morphological features have to be estimated in fish cultures on a daily basis
Two approaches are combined for estimating the aforementioned morphological parameters from photographs that have been captured using a single camera: (1) image processing based on novel edge detection, pattern matching and shape rotation techniques and (2) deep learning techniques that lead to the estimation of eight landmarks
We focus on profile fish photographs taken from the side of the fish
Summary
Various fish morphological features have to be estimated in fish cultures on a daily basis. Two approaches are combined for estimating the aforementioned morphological parameters from photographs that have been captured using a single camera: (1) image processing based on novel edge detection, pattern matching and shape rotation techniques and (2) deep learning techniques (mask region-CNN, GrabCut [24]) that lead to the estimation of eight landmarks The results of these approaches differ in their speed and the achieved accuracy, depending on the conditions of the photograph (e.g., background complexity, light exposure and existence of multiple fish), but may operate in a complementary way, as will be described .
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
