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Deep learning-based restoration of multi-degraded finger-vein image by non-uniform illumination and noise

Jin Seong Hong, Seung Gu Kim, Jung Soo Kim, Kang Ryoung Park

2024Engineering Applications of Artificial Intelligence17 citationsDOIOpen Access PDF

Abstract

The recognition performance deteriorates if degradation factors including blur, noise, and non-uniform illumination exist in the image when acquiring a finger-vein image. Especially, multiple degradation factors can occur when acquiring the finger-vein image, and they require the image restoration. However, previous flow-based model produced lower image quality than the other restoration models, and diffusion-based model had the disadvantage of slow inference speed. Therefore, this study suggests a deep learning-based generative adversarial network for multi-degraded finger-vein image restoration by non-uniform illumination and noise (MFNN-GAN). It considers multiple degradation factors such as non-uniform illumination and noise. Unlike the existing finger-vein image restoration model, MFNN-GAN is capable of adaptive restoration to multiple degradations. Therefore, even if the illumination by near-infrared (NIR) illuminator of finger-vein recognition device is weak or non-uniform, or the consequent captured image is noisy, good recognition performance can be achieved only by our method without replacing the illuminator or camera sensor. The experimental results obtained using finger-vein open datasets, session 1 images from database version 1 of the Hong Kong Polytechnic University finger-image (HKPU-DB) and finger-vein database of SDUMLA-HMT (SDUMLA-HMT-DB)-based degraded databases. The experimental results show that we obtained the lower equal error rate (EER) of finger-vein recognition using MFNN-GAN compared to other state-of-the-art algorithms.

Topics & Concepts

Computer scienceArtificial intelligenceNoise (video)Image restorationComputer visionImage (mathematics)Degradation (telecommunications)Image qualityImage processingTelecommunicationsAdvanced Image Processing TechniquesImage and Signal Denoising MethodsDigital Media Forensic Detection