FundusPosNet: A Deep Learning Driven Heatmap Regression Model for the Joint Localization of Optic Disc and Fovea Centers in Color Fundus Images

The localization of the optic disc and fovea is crucial in the automated diagnosis of various retinal diseases. We propose a novel deep learning driven heatmap regression model based on the encoder-decoder architecture for the joint detection of optic disc and fovea centers in color fundus images. T...

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Bibliographic Details
Published inIEEE access Vol. 9; pp. 159071 - 159080
Main Authors Bhatkalkar, Bhargav J., Nayak, S. Vighnesh, Shenoy, Sathvik V., Arjunan, R. Vijaya
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 2021
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Adaptive optics
Biomedical optical imaging
Coders
Color
Datasets
Deep learning
Encoders-Decoders
Fovea
Fundus image
Gaussian blob
Heating systems
heatmap
Localization
Mathematical models
Medical imaging
Model testing
Nonlinear optics
optic disc
Optical imaging
Regression models
regression neural network
Retina
Two dimensional models
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Summary:The localization of the optic disc and fovea is crucial in the automated diagnosis of various retinal diseases. We propose a novel deep learning driven heatmap regression model based on the encoder-decoder architecture for the joint detection of optic disc and fovea centers in color fundus images. To train the regression model, we transform the ground-truth center coordinates of optic disc and fovea of the IDRiD dataset to heatmaps using a 2D-Gaussian equation. The model is capable of pinpointing any single pixel in a vast 2D image space. The model is tested on IDRiD test dataset, Messidor, and G1020 datasets. The model outperforms the state-of-the-art methods on these datasets. The model is very robust and generic, which can be trained and used for the simultaneous localization of multiple landmarks in different medical image datasets. The full implementation code and the trained model with weights (based on Keras) are available for reuse at https://github.com/bhargav-jb/FundusPosNet .
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2021.3127280