AI Article Synopsis
- The study addresses the challenges in predicting visual quality of binocular images due to discrepancies between left and right views.
- The authors propose a hierarchical feature fusion network (HFFNet) that effectively processes these discrepancies using multiple levels of fusion between the two views.
- HFFNet utilizes MobileNetV2 for feature extraction and combines low, middle, and high-level features to enhance distortion detection, achieving superior performance compared to current methods on benchmark datasets.
Article Abstract
Compared with monocular images, scene discrepancies between the left- and right-view images impose additional challenges on visual quality predictions in binocular images. Herein, we propose a hierarchical feature fusion network (HFFNet) for blind binocular image quality prediction that handles scene discrepancies and uses multilevel fusion features from the left- and right-view images to reflect distortions in binocular images. Specifically, a feature extraction network based on MobileNetV2 is used to determine the feature layers from distorted binocular images; then, low-level binocular fusion features (or middle-level and high-level binocular fusion features) are obtained by fusing the left and right low-level monocular features (or middle-level and high-level monocular features) using the feature gate module; further, three feature enhancement modules are used to enrich the information of the extracted features at different levels. Finally, the total feature maps obtained from the high-, middle-, and low-level fusion features are applied to a three-input feature fusion module for feature merging. Thus, the proposed HFFNet provides better results, to the best of our knowledge, than existing methods on two benchmark datasets.
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| http://dx.doi.org/10.1364/AO.465349 | DOI Listing |
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