PointNet++ and Three Layers of Features Fusion for Occlusion Three-Dimensional Ear Recognition Based on One Sample per Person

Zhu, Qinping; Zhang, Mu

doi:10.3390/sym12010078

Cited by 10 publications

(11 citation statements)

References 24 publications

(92 reference statements)

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“…Third, the ICP method [23] must search the entire surface of the gallery ear image for the point closest to the point from the probe sample. Furthermore, feature fusion method [31][32][33]38], surface variation feature extraction method [21], and index method [40] must search the entire surface of the gallery ear image for the match of the query feature. Consequently, these methods require more time to search the matching feature than the proposed system.…”

Section: Comparison With Existing Methodsmentioning

confidence: 99%

“…However, when these indicators are used to evaluate the LC_KSVD method [24], which is difficult to run on the OSPP gallery, it is difficult to use the running time of the LC_KSVD method applied to the gallery composed of multiple samples of each subject to represent the running time of the LC_KSVD method applied to the OSPP gallery. Moreover, when applied to methods [7, 21, 23, 31–33, 38, 40], the time required of one identification operation is easily affected by the scale of the OSPP gallery, that is, with the expansion of the scale of the OSPP gallery, the time required of one identification operation is easy to increase. To solve these problems, we propose an indicator: the time of one identification operation shared by each gallery subject (TOIOS‐EGS).…”

Section: Methodsmentioning

confidence: 99%

“…Hence, for this method [24], TOIOS‐EGS obtained using a gallery containing 762 samples of 127 subjects was considered to be equal to that obtained using an OSPP gallery. Furthermore, the number of features considered in previous works [7, 21, 23, 31–33, 38, 40] and in our CKC‐SR methods required to match is approximately proportional to the number of subjects that comprise the OSPP gallery. Hence, when applied to the OSPP gallery with different scales, the TOIOS‐EGS of any among these methods does not show any remarkable difference.…”

Section: Methodsmentioning

confidence: 99%

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Corresponding keypoint constrained sparse representation three‐dimensional ear recognition via one sample per person

Zhu

Zhang

2022

IET Biometrics

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When only one sample per person (OSPP) is registered in the gallery, it is difficult for ear recognition methods to sufficiently and effectively reduce the search range of the matching features, thus resulting in low computational efficiency and mismatch problems. A 3D ear biometric system using OSPP is proposed to solve this problem. By categorising ear images by shape and establishing the corresponding relationship between keypoints from ear images and regions (regional cluster) on the directional proposals that can be arranged to roughly face the ear image, the corresponding keypoints are obtained. Then, ear recognition is performed by combining corresponding keypoints and a multikeypoint descriptor sparse representation classification method. The experimental results conducted on the University of Notre Dame Collection J2 dataset yielded a rank-1 recognition rate of 98.84%; furthermore, the time for one identification operation shared by each gallery subject was 0.047 ms.

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Section: Comparison With Existing Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Corresponding keypoint constrained sparse representation three‐dimensional ear recognition via one sample per person

Zhu

Zhang

2022

IET Biometrics

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“…Similarly, SECOND [28] applies sparse convolution to get efficient features from voxels. F-PointNet [29] uses a 2D object detector on the image to make 2D object proposal first and then get corresponding frustum point cloud as the base of regression and prediction, while the accuracy of F-PointNet relies too much on the 2D detector.…”

Section: Related Workmentioning

confidence: 99%

“…( 27) else (28) add new voxel in hash table. (29) end if (30) end if (31) end for ALGORITHM 1: Voxelization algorithm. Mobile Information Systems form a square receptive field, the introduction of deformable convolution can better adapt to the changes of different directions of vehicles.…”

Section: Network Architecture Point Cloud Feature Aelectionmentioning

confidence: 99%

Learning Deformable Network for 3D Object Detection on Point Clouds

Zhang

2021

Mobile Information Systems

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3D object detection based on point cloud data in the unmanned driving scene has always been a research hotspot in unmanned driving sensing technology. With the development and maturity of deep neural networks technology, the method of using neural network to detect three-dimensional object target begins to show great advantages. The experimental results show that the mismatch between anchor and training samples would affect the detection accuracy, but it has not been well solved. The contributions of this paper are as follows. For the first time, deformable convolution is introduced into the point cloud object detection network, which enhances the adaptability of the network to vehicles with different directions and shapes. Secondly, a new generation method of anchor in RPN is proposed, which can effectively prevent the mismatching between the anchor and ground truth and remove the angle classification loss in the loss function. Compared with the state-of-the-art method, the AP and AOS of the detection results are improved.

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