DA-Net: Learning the Fine-Grained Density Distribution With Deformation Aggregation Network

The major challenges for accurate crowd counting stem from the large variations in the scale, shape, and perspective. In fact, dealing with such difficulties depends on the geometric transformation capabilities of the network. Thus, we propose the deformation aggregation network (DA-Net) that can in...

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Bibliographic Details
Published in:IEEE access 2018, Vol.6, p.60745-60756
Main Authors: Zou, Zhikang, Su, Xinxing, Qu, Xiaoye, Zhou, Pan
Format: Article
Language:English
Subjects:
Adaptation models
adaptive receptive fields
Agglomeration
Crowd counting
deformable convolution
Deformation
Density distribution
Diamond
Diamonds
Feature extraction
fine-grained density distribution
Formability
Geometric transformation
Kernel
Offsets
Spatial data
Strain
Switches
Training
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Summary:The major challenges for accurate crowd counting stem from the large variations in the scale, shape, and perspective. In fact, dealing with such difficulties depends on the geometric transformation capabilities of the network. Thus, we propose the deformation aggregation network (DA-Net) that can incrementally incorporate adaptive receptive fields to capture the fine-grained density distribution. Our model starts from a fundamental diamond network based on the successive steps of rising and falling on the channels, which utilizes small-fixed kernels accounting for preserving spatial information. For sake of accommodating to scale variations, we further apply deformable convolutions to deliver precise localization by augmenting the spatial sampling locations with additional offsets, capable of transformation-invariant speciality on diverse scenes. In addition, we assign adjustable weights to supervise network to learn the fusion proportion adaptively and aggregate multiple levels of abstractions to get the final density map. DA-Net is a fully convolutional network that is able to take input of arbitrary size. The proposed method delivers the state-of-the-art performance on four benchmarks (ShanghaiTech, WorldExpo'10, UCSD, and UCF_CC_50). To further verify the generality of our model, we conduct an extended experiment on vehicle data set TRANCOS and achieve significant results.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2018.2875495