Abstract
It is known that the human visual system performs a hierarchical information process in which early vision cues (or primitives) are fused in the visual cortex to compose complex shapes and descriptors. While different aspects of the process have been extensively studied, such as lens adaptation or feature detection, some other aspects, such as feature fusion, have been mostly left aside. In this work, we elaborate on the fusion of early vision primitives using generalizations of the Choquet integral, and novel aggregation operators that have been extensively studied in recent years. We propose to use generalizations of the Choquet integral to sensibly fuse elementary edge cues, in an attempt to model the behaviour of neurons in the early visual cortex. Our proposal leads to a fully-framed edge detection algorithm whose performance is put to the test in state-of-the-art edge detection datasets.
Highlights
The Human Visual System (HVS) has been, historically, a source of inspiration for researchers in computer vision
We have proposed a different use of the generalizations of the Choquet integral for aggregating information in images, concretely for fusing extracted image features in the context of edge detection
We are able to represent the relationship between all the variations of intensity around each pixel, considering some directions, simulating in a better way the process done in the HVS
Summary
The Human Visual System (HVS) has been, historically, a source of inspiration for researchers in computer vision. It is well known that the human visual system does not consist of randomly connected layers of neural networks coping with the information gathered by cones and rods Instead, it features a more evolved system in which information is subsequently analysed to detect basic shapes, which are further combined to detect more complex structures. Humans are known to have center-surround receptive fields at the retina, which are further combined at the Early Visual Cortex (V1) to compose lines, boundaries, etc. This discovery had a massive impact in computer vision in the early 80’s, and led to the introduction of Marr-Hildreth’s Laplacian-based edge detection method [9, 10]. This edge detection method aimed at faithfully simulating the role of retinal ganglions using Laplacian
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