Convolutional Neural Network-Based Finger-Vein Recognition Using NIR Image Sensors

Hong, Hyung Gil; Lee, Min Beom; Park, Kang Ryoung

doi:10.3390/s17061297

Cited by 150 publications

(55 citation statements)

References 44 publications

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“…The captured finger images are binarized, and the binarized images are used to restore the collapsed areas through the convex hull algorithm [ 34 ] to extract accurate finger regions. Then, a 4 × 20 mask is used to detect the upper and lower boundaries to extract the finger regions more accurately than [ 18 , 32 ] (step 2 of Figure 1 ). After this, the in-plane rotation of the extracted finger region is calibrated (step 3) to obtain the final ROI image for CNN input (step 4).…”

Section: Proposed Methodsmentioning

confidence: 99%

“…In this research, to solve these problems, in-plane rotation compensation was conducted on the input finger images. As shown in Figure 2 d, for an accurate rotation angle measurement in the obtained finger images, a 4 × 20 mask was used to detect the upper and lower boundaries of finger-veins, as shown in the red-colored lines of Figure 3 b [ 18 , 32 ]. After this, the two-dimensional moment of the finger region between these two boundaries is calculated and used for in-plane rotation compensation [ 35 ].…”

Section: Proposed Methodsmentioning

confidence: 99%

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Multimodal Biometric Recognition Based on Convolutional Neural Network by the Fusion of Finger-Vein and Finger Shape Using Near-Infrared (NIR) Camera Sensor

Kim

Song

Park

2018

Sensors

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Finger-vein recognition, which is one of the conventional biometrics, hinders fake attacks, is cheaper, and it features a higher level of user-convenience than other biometrics because it uses miniaturized devices. However, the recognition performance of finger-vein recognition methods may decrease due to a variety of factors, such as image misalignment that is caused by finger position changes during image acquisition or illumination variation caused by non-uniform near-infrared (NIR) light. To solve such problems, multimodal biometric systems that are able to simultaneously recognize both finger-veins and fingerprints have been researched. However, because the image-acquisition positions for finger-veins and fingerprints are different, not to mention that finger-vein images must be acquired in NIR light environments and fingerprints in visible light environments, either two sensors must be used, or the size of the image acquisition device must be enlarged. Hence, there are multimodal biometrics based on finger-veins and finger shapes. However, such methods recognize individuals that are based on handcrafted features, which present certain limitations in terms of performance improvement. To solve these problems, finger-vein and finger shape multimodal biometrics using near-infrared (NIR) light camera sensor based on a deep convolutional neural network (CNN) are proposed in this research. Experimental results obtained using two types of open databases, the Shandong University homologous multi-modal traits (SDUMLA-HMT) and the Hong Kong Polytechnic University Finger Image Database (version 1), revealed that the proposed method in the present study features superior performance to the conventional methods.

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Section: Proposed Methodsmentioning

confidence: 99%

Section: Proposed Methodsmentioning

confidence: 99%

Multimodal Biometric Recognition Based on Convolutional Neural Network by the Fusion of Finger-Vein and Finger Shape Using Near-Infrared (NIR) Camera Sensor

Kim

Song

Park

2018

Sensors

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“…In addition, conventional approaches require complex and complicated preprocessing and feature extraction, steps which need much more processing time and effort. To alleviate these problems, Hyung et al [126] proposed a robust deep CNN model and an error rate of 0.396 was attained on a good quality database. Moreover, Gesi et al [127] applied a convolutional neural network (CNN) finger vein recognition method and achieved almost 100% accuracy, obtaining a very low error rate of 0.21.…”

Section: Finger Vein Recognition Using Deep Learning Methodsmentioning

confidence: 99%

A Systematic Review of Finger Vein Recognition Techniques

Han-gang²,

et al. 2018

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Biometric identification is the study of physiological and behavioral attributes of an individual to overcome security problems. Finger vein recognition is a biometric technique used to analyze finger vein patterns of persons for proper authentication. This paper presents a detailed review on finger vein recognition algorithms. Such tools include image acquisition, preprocessing, feature extraction and matching methods to extract and analyze object patterns. In addition, we list some novel findings after the critical comparative analysis of the highlighted techniques. The comparative studies indicate that the accuracy of finger vein identification methods is up to the mark.

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“…Biometrics in both physiological and behavioral forms are delivering an efficient platform for security metrics [ 1 ]. Physiological biometrics include fingerprint recognition [ 2 ], finger vein pattern recognition [ 3 ], face recognition [ 4 ], iris recognition [ 5 ], and palmprint recognition [ 6 ]. Iris recognition has been proven as innovative reliable biometric widely used in security, authentication, and identification systems [ 7 ].…”

Section: Introductionmentioning

confidence: 99%

IrisDenseNet: Robust Iris Segmentation Using Densely Connected Fully Convolutional Networks in the Images by Visible Light and Near-Infrared Light Camera Sensors

Arsalan

Naqvi

Kim

et al. 2018

Sensors

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The recent advancements in computer vision have opened new horizons for deploying biometric recognition algorithms in mobile and handheld devices. Similarly, iris recognition is now much needed in unconstraint scenarios with accuracy. These environments make the acquired iris image exhibit occlusion, low resolution, blur, unusual glint, ghost effect, and off-angles. The prevailing segmentation algorithms cannot cope with these constraints. In addition, owing to the unavailability of near-infrared (NIR) light, iris recognition in visible light environment makes the iris segmentation challenging with the noise of visible light. Deep learning with convolutional neural networks (CNN) has brought a considerable breakthrough in various applications. To address the iris segmentation issues in challenging situations by visible light and near-infrared light camera sensors, this paper proposes a densely connected fully convolutional network (IrisDenseNet), which can determine the true iris boundary even with inferior-quality images by using better information gradient flow between the dense blocks. In the experiments conducted, five datasets of visible light and NIR environments were used. For visible light environment, noisy iris challenge evaluation part-II (NICE-II selected from UBIRIS.v2 database) and mobile iris challenge evaluation (MICHE-I) datasets were used. For NIR environment, the institute of automation, Chinese academy of sciences (CASIA) v4.0 interval, CASIA v4.0 distance, and IIT Delhi v1.0 iris datasets were used. Experimental results showed the optimal segmentation of the proposed IrisDenseNet and its excellent performance over existing algorithms for all five datasets.

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Convolutional Neural Network-Based Finger-Vein Recognition Using NIR Image Sensors

Cited by 150 publications

References 44 publications

Multimodal Biometric Recognition Based on Convolutional Neural Network by the Fusion of Finger-Vein and Finger Shape Using Near-Infrared (NIR) Camera Sensor

Multimodal Biometric Recognition Based on Convolutional Neural Network by the Fusion of Finger-Vein and Finger Shape Using Near-Infrared (NIR) Camera Sensor

A Systematic Review of Finger Vein Recognition Techniques

IrisDenseNet: Robust Iris Segmentation Using Densely Connected Fully Convolutional Networks in the Images by Visible Light and Near-Infrared Light Camera Sensors

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