2022
Bhole, Amey; Udmale, Sandeep S; Falzon, Owen; Azzopardi, George
CORF3D contour maps with application to Holstein cattle recognition from RGB and thermal images Journal Article
Abstract | Links | BibTeX | Altmetric | Tags: brain-inspired, contour detection, convnets, deep learning, noise suppression, pattern recognition, smart farming
@article{bhole2022corf3d,
title = {CORF3D contour maps with application to Holstein cattle recognition from RGB and thermal images},
author = {Amey Bhole and Sandeep S Udmale and Owen Falzon and George Azzopardi},
doi = {https://doi.org/10.1016/j.eswa.2021.116354},
year = {2022},
date = {2022-01-01},
urldate = {2022-01-01},
journal = {Expert Systems with Applications},
volume = {192},
number = {116354},
publisher = {Pergamon},
abstract = {Livestock management involves the monitoring of farm animals by tracking certain physiological and phenotypical characteristics over time. In the dairy industry, for instance, cattle are typically equipped with RFID ear tags. The corresponding data (e.g. milk properties) can then be automatically assigned to the respective cow when they enter the milking station. In order to move towards a more scalable, affordable, and welfare-friendly approach, automatic non-invasive solutions are more desirable. Thus, a non-invasive approach is proposed in this paper for the automatic identification of individual Holstein cattle from the side view while exiting a milking station. It considers input images from a thermal-RGB camera. The thermal images are used to delineate the cow from the background. Subsequently, any occluding rods from the milking station are removed and inpainted with the fast marching algorithm. Then, it extracts the RGB map of the segmented cattle along with a novel CORF3D contour map. The latter contains three contour maps extracted by the Combination of Receptive Fields (CORF) model with different strengths of push\textendashpull inhibition. This mechanism suppresses noise in the form of grain type texture. The effectiveness of the proposed approach is demonstrated by means of experiments using a 5-fold and a leave-one day-out cross-validation on a new data set of 3694 images of 383 cows collected from the Dairy Campus in Leeuwarden (the Netherlands) over 9 days. In particular, when combining RGB and CORF3D maps by late fusion, an average accuracy of was obtained for the 5-fold cross validation and for the leave-one day-out experiment. The two maps were combined by first learning two ConvNet classification models, one for each type of map. The feature vectors in the two FC layers obtained from training images were then concatenated and used to learn a linear SVM classification model. In principle, the proposed approach with the novel CORF3D contour maps is suitable for various image classification applications, especially where grain type texture is a confounding variable.},
keywords = {brain-inspired, contour detection, convnets, deep learning, noise suppression, pattern recognition, smart farming},
pubstate = {published},
tppubtype = {article}
}
2020
Melotti, Damiano; Heimbach, Kevin; Rodríguez-Sánchez, Antonio; Strisciuglio, Nicola; Azzopardi, George
A robust contour detection operator with combined push-pull inhibition and surround suppression Journal Article
Abstract | Links | BibTeX | Altmetric | Tags: brain-inspired, contour detection, noise suppression
@article{melotti2020robust,
title = {A robust contour detection operator with combined push-pull inhibition and surround suppression},
author = {Damiano Melotti and Kevin Heimbach and Antonio Rodr\'{i}guez-S\'{a}nchez and Nicola Strisciuglio and George Azzopardi},
doi = {https://doi.org/10.1016/j.ins.2020.03.026},
year = {2020},
date = {2020-01-01},
urldate = {2020-01-01},
journal = {Information Sciences},
volume = {524},
pages = {229-240},
publisher = {2020},
abstract = {Contour detection is a salient operation in many computer vision applications as it extracts features that are important for distinguishing objects in scenes. It is believed to be a primary role of simple cells in visual cortex of the mammalian brain. Many of such cells receive push-pull inhibition or surround suppression. We propose a computational model that exhibits a combination of these two phenomena. It is based on two existing models, which have been proven to be very effective for contour detection. In particular, we introduce a brain-inspired contour operator that combines push-pull and surround inhibition. It turns out that this combination results in a more effective contour detector, which suppresses texture while keeping the strongest responses to lines and edges, when compared to existing models. The proposed model consists of a Combination of Receptive Field (or CORF) model with push-pull inhibition, extended with surround suppression. We demonstrate the effectiveness of the proposed approach on the RuG and Berkeley benchmark data sets of 40 and 500 images, respectively. The proposed push-pull CORF operator with surround suppression outperforms the one without suppression with high statistical significance.},
keywords = {brain-inspired, contour detection, noise suppression},
pubstate = {published},
tppubtype = {article}
}
2019
Strisciuglio, Nicola; Azzopardi, George; Petkov, Nicolai
Robust Inhibition-augmented Operator for Delineation of Curvilinear Structures Journal Article
Abstract | Links | BibTeX | Altmetric | Tags: brain-inspired, contour detection, noise suppression, trainable filters
@article{strisciuglio2019robust,
title = {Robust Inhibition-augmented Operator for Delineation of Curvilinear Structures},
author = {Nicola Strisciuglio and George Azzopardi and Nicolai Petkov},
doi = {10.1109/TIP.2019.2922096},
year = {2019},
date = {2019-01-01},
urldate = {2019-01-01},
journal = {IEEE Transactions on Image Processing},
volume = {28},
number = {12},
pages = {5852--5866},
publisher = {IEEE},
abstract = {Delineation of curvilinear structures in images is an important basic step of several image processing applications, such as segmentation of roads or rivers in aerial images, vessels or staining membranes in medical images, and cracks in pavements and roads, among others. Existing methods suffer from insufficient robustness to noise. In this paper, we propose a novel operator for the detection of curvilinear structures in images, which we demonstrate to be robust to various types of noise and effective in several applications. We call it RUSTICO, which stands for RobUST Inhibition-augmented Curvilinear Operator. It is inspired by the push-pull inhibition in visual cortex and takes as input the responses of two trainable B-COSFIRE filters of opposite polarity. The output of RUSTICO consists of a magnitude map and an orientation map. We carried out experiments on a data set of synthetic stimuli with noise drawn from different distributions, as well as on several benchmark data sets of retinal fundus images, crack pavements, and aerial images and a new data set of rose bushes used for automatic gardening. We evaluated the performance of RUSTICO by a metric that considers the structural properties of line networks (connectivity, area, and length) and demonstrated that RUSTICO outperforms many existing methods with high statistical significance. RUSTICO exhibits high robustness to noise and texture.},
keywords = {brain-inspired, contour detection, noise suppression, trainable filters},
pubstate = {published},
tppubtype = {article}
}
2014
Azzopardi, George; Rodríguez-Sánchez, Antonio; Piater, Justus; Petkov, Nicolai
A push-pull CORF model of a simple cell with antiphase inhibition improves SNR and contour detection Journal Article
Abstract | Links | BibTeX | Altmetric | Tags: brain-inspired, contour detection, noise suppression, trainable filters
@article{azzopardi2014push,
title = {A push-pull CORF model of a simple cell with antiphase inhibition improves SNR and contour detection},
author = {George Azzopardi and Antonio Rodr\'{i}guez-S\'{a}nchez and Justus Piater and Nicolai Petkov},
doi = {https://doi.org/10.1371/journal.pone.0098424},
year = {2014},
date = {2014-01-01},
urldate = {2014-01-01},
journal = {PLoS One},
publisher = {2014},
abstract = {We propose a computational model of a simple cell with push-pull inhibition, a property that is observed in many real simple cells. It is based on an existing model called Combination of Receptive Fields or CORF for brevity. A CORF model uses as afferent inputs the responses of model LGN cells with appropriately aligned center-surround receptive fields, and combines their output with a weighted geometric mean. The output of the proposed model simple cell with push-pull inhibition, which we call push-pull CORF, is computed as the response of a CORF model cell that is selective for a stimulus with preferred orientation and preferred contrast minus a fraction of the response of a CORF model cell that responds to the same stimulus but of opposite contrast. We demonstrate that the proposed push-pull CORF model improves signal-to-noise ratio (SNR) and achieves further properties that are observed in real simple cells, namely separability of spatial frequency and orientation as well as contrast-dependent changes in spatial frequency tuning. We also demonstrate the effectiveness of the proposed push-pull CORF model in contour detection, which is believed to be the primary biological role of simple cells. We use the RuG (40 images) and Berkeley (500 images) benchmark data sets of images with natural scenes and show that the proposed model outperforms, with very high statistical significance, the basic CORF model without inhibition, Gabor-based models with isotropic surround inhibition, and the Canny edge detector. The push-pull CORF model that we propose is a contribution to a better understanding of how visual information is processed in the brain as it provides the ability to reproduce a wider range of properties exhibited by real simple cells. As a result of push-pull inhibition a CORF model exhibits an improved SNR, which is the reason for a more effective contour detection.},
keywords = {brain-inspired, contour detection, noise suppression, trainable filters},
pubstate = {published},
tppubtype = {article}
}
2012
Azzopardi, George; Petkov, Nicolai
A CORF computational model of a simple cell that relies on LGN input outperforms the Gabor function model Journal Article
Abstract | Links | BibTeX | Altmetric | Tags: brain-inspired, contour detection
@article{azzopardi2012corf,
title = {A CORF computational model of a simple cell that relies on LGN input outperforms the Gabor function model},
author = {George Azzopardi and Nicolai Petkov},
doi = {https://doi.org/10.1007/s00422-012-0486-6},
year = {2012},
date = {2012-01-01},
urldate = {2012-01-01},
journal = {Biological cybernetics},
volume = {106},
pages = {177-189},
publisher = {Springer-Verlag},
abstract = {Simple cells in primary visual cortex are believed to extract local contour information from a visual scene. The 2D Gabor function (GF) model has gained particular popularity as a computational model of a simple cell. However, it short-cuts the LGN, it cannot reproduce a number of properties of real simple cells, and its effectiveness in contour detection tasks has never been compared with the effectiveness of alternative models. We propose a computational model that uses as afferent inputs the responses of model LGN cells with center\textendashsurround receptive fields (RFs) and we refer to it as a Combination of Receptive Fields (CORF) model. We use shifted gratings as test stimuli and simulated reverse correlation to explore the nature of the proposed model. We study its behavior regarding the effect of contrast on its response and orientation bandwidth as well as the effect of an orthogonal mask on the response to an optimally oriented stimulus. We also evaluate and compare the performances of the CORF and GF models regarding contour detection, using two public data sets of images of natural scenes with associated contour ground truths. The RF map of the proposed CORF model, determined with simulated reverse correlation, can be divided in elongated excitatory and inhibitory regions typical of simple cells. The modulated response to shifted gratings that this model shows is also characteristic of a simple cell. Furthermore, the CORF model exhibits cross orientation suppression, contrast invariant orientation tuning and response saturation. These properties are observed in real simple cells, but are not possessed by the GF model. The proposed CORF model outperforms the GF model in contour detection with high statistical confidence (RuG data set: p < 10−4, and Berkeley data set: p < 10−4). The proposed CORF model is more realistic than the GF model and is more effective in contour detection, which is assumed to be the primary biological role of simple cells.},
keywords = {brain-inspired, contour detection},
pubstate = {published},
tppubtype = {article}
}