A Gated Peripheral-Foveal Convolutional Neural Network for Unified Image Aesthetic Prediction

Learning fine-grained details is a key issue in image aesthetic assessment. Most of the previous methods extract the fine-grained details via random cropping strategy, which may undermine the integrity of semantic information. Extensive studies show that humans perceive fine-grained details with a m...

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Bibliographic Details
Published inIEEE transactions on multimedia Vol. 21; no. 11; pp. 2815 - 2826
Main Authors Zhang, Xiaodan, Gao, Xinbo, Lu, Wen, He, Lihuo
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 01.11.2019
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Artificial neural networks
Convolutional neural networks
Data integration
Datasets
Deep learning
Feature extraction
Fovea
image aesthetics
Image resolution
Logic gates
Multisensor fusion
Neural networks
Peripheral vision
Regression analysis
Task analysis
Visual acuity
Visual aesthetic quality assessment
Visual stimuli
Visualization
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Summary:Learning fine-grained details is a key issue in image aesthetic assessment. Most of the previous methods extract the fine-grained details via random cropping strategy, which may undermine the integrity of semantic information. Extensive studies show that humans perceive fine-grained details with a mixture of foveal vision and peripheral vision. Fovea has the highest possible visual acuity and is responsible for seeing the details. The peripheral vision is used for perceiving the broad spatial scene and selecting the attended regions for the fovea. Inspired by these observations, we propose a gated peripheral-foveal convolutional neural network. It is a dedicated double-subnet neural network (i.e., a peripheral subnet and a foveal subnet). The former aims to mimic the functions of peripheral vision to encode the holistic information and provide the attended regions. The latter aims to extract fine-grained features on these key regions. Considering that the peripheral vision and foveal vision play different roles in processing different visual stimuli, we further employ a gated information fusion network to weigh their contributions. The weights are determined through the fully connected layers followed by a sigmoid function. We conduct comprehensive experiments on the standard Aesthetic Visual Analysis (AVA) dataset and Photo.net dataset for unified aesthetic prediction tasks: 1) aesthetic quality classification; 2) aesthetic score regression; and 3) aesthetic score distribution prediction. The experimental results demonstrate the effectiveness of the proposed method.
ISSN:1520-9210
1941-0077
DOI:10.1109/TMM.2019.2911428