IS&T | Library

Assessing the Quality of Light Field Images: A Graph-based Approach

8 0

quality assessment
graph convolutional neural network
light field images
epipolar plane images

Sana Alamgeer, Muhammad Irshad, Mylène C. Q. Farias

Pages 1 - 7, © Society for Imaging Science and Technology 2025

DOI

10.2352/J.ImagingSci.Technol.2025.69.4.040507

CAPT 2024 Latest Innovations on Printing and Packaging Technologies

Abstract

Light fields (LFs) capture both angular and spatial information of light rays, providing an immersive and detailed representation of the visual world. However, the high dimensionality of LF data presents challenges for compression and transmission algorithms, which often introduce degradations that affect visual quality. To address this, we propose GCNN-LFIQA, a novel no-reference LF image quality assessment method that leverages the power of deep graph convolutional neural networks (GCNNs). The method employs a single-stream deep GCNN architecture to model the complex structural and geometric relationships within LF data, enabling accurate quality predictions. A key innovation of the proposed approach is its input preparation pipeline, which converts horizontal epipolar plane images into skeleton-based graph representations enriched with node-level features such as betweenness centrality. These graph representations serve as input to the GCNN, which predicts quality scores using a regression block. We evaluated GCNN-LFIQA on two widely used LF quality datasets, Win5-LID and LFDD, where it achieved high correlation values and outperformed other state-of-the-art methods. The proposed method demonstrates robustness, computational efficiency, and the potential to address the unique challenges of LF image quality assessment in real-world applications.

Digital Library: JIST

FastTrack Article

50 0

Near-Field Dynamic Response of Honeycomb Paperboard under Impact

finite element method
impact
honeycomb paperboard
deformation mode

Gaimei Zhang, Danyang Li, Jinging Hu, Lehao Lin, Hui Liu, Xiaoli Song, Jiandong Lu, Jiazi Shi, Yonggang Yang, Jiayi Feng

Pages 1 - 11, © Society for Imaging Science and Technology 2025

DOI

10.2352/J.ImagingSci.Technol.2025.69.3.030411

Abstract

As a porous sandwich plate system, the honeycomb paperboard is widely used in cushioning packaging of products due to its energy-absorbing properties. The drop impact on a honeycomb paperboard with cell sizes of 4 mm, 6 mm, and 8 mm was simulated and experimented to investigate the paperboard’s energy absorption and deformation modes. The peak impact force of the impactor with velocity 5.47 m s⁻¹, the dent depth of the honeycomb paperboard, and the absorbed energy were obtained. The peak forces corresponding to the core layer cell sizes of 4 mm, 6 mm, and 8 mm were 141.2 N, 108.7 N, and 97.7 N, and the absorbed energy values were 76%, 83%, and 84%, respectively. The model of honeycomb paperboard under drop impact was established. The plastic deformation and force distribution showed good agreement with experimental results, which verified the accuracy of the model. The results are expected to provide a reference for the lightweight structure and protective design of the honeycomb paperboard.

Digital Library: JIST

FastTrack Article

A Multiple Diffusion Color Image Encryption Algorithm based on 6D Cellular Neural Networks

43 2

cellular neural network
4D hyperchaos system
color image encryption
chaotic sequence encryption

Ziwei Zhou, Wenxia Xu, Xiangkun Chen, Guodong Li

Pages 1 - 14, © Society for Imaging Science and Technology 2025

DOI

10.2352/J.ImagingSci.Technol.2025.69.4.040505

Abstract

To boost the security of color image encryption algorithms and enlarge their key space, an encryption algorithm of color image based on cellular neural networks (CNNs) is proposed. The sequence produced by the 6D CNN system is segmented into two groups and combined at a specific ratio. The new chaotic sequence obtained is used as the key source for a 4D hyperchaos system. The key is selected based on the logical operation results of the plaintext pixel mean, and the final chaotic encryption sequences X and Y are obtained. Pixel scrambling, diffusion on each layer of R, G, B, and pixel value replacement encryption operations are performed on color images, which are encrypted as ciphertext images. The results of the experimental simulation demonstrate that the image encryption algorithm outlined in this paper possesses significant key space, robust sensitivity to both keys and plaintext, uniform distribution of ciphertext pixels, and a correlation coefficient near 0 among neighboring pixels. It is capable of effectively thwarting exhaustive attacks, statistical analysis attacks, and differential attacks, and produces a notable encryption impact on color images. It possesses specific utility in the realm of color image information security.

Digital Library: JIST

FastTrack Article

Efficient Image Compression with Transformer and Convolutional Dual Channel Networks

68 5

image compression
transformer
deep learning
content-adaptive transform

Jianhua Hu, Guixiang Luo, Zhangjiang Yuan, Weimei Wu, Mengjun Ding, Wei Nie, Yaohua Liang, Xiangfei Feng

Pages 1 - 13, © Society for Imaging Science and Technology 2025

DOI

10.2352/J.ImagingSci.Technol.2025.69.4.040504

CAPT 2024 Latest Innovations on Printing and Packaging Technologies

Abstract

Image compression is an essential technology in image processing as it reduces video storage, which is increasingly popular. Deep learning-based image compression has made significant progress, surpassing traditional coding and decoding approaches in specific cases. Current methods employ autoencoders, typically consisting of convolutional neural networks, to map input images to lower-dimensional latent spaces for compression. However, these approaches often overlook low-frequency information, leading to sub-optimal compression performance. To address this challenge, this study proposed a novel image compression technique, Transformer and Convolutional Dual Channel Networks (TCDCN). This method extracts both edge detail and low-frequency information, achieving a balance between high and low-frequency compression. The study also utilized a variational autoencoder architecture with parallel stacked transformer and convolutional networks to create a compact representation of the input image through end-to-end training. This content-adaptive transform captured low-frequency information dynamically, leading to improved compression efficiency. Compared to the classic JPEG method, our model showed significant improvements in Bjontegaard Delta rate up to 19.12% and 18.65% on Kodak and CLIC test datasets, respectively. These improvements also surpassed the state-of-the-art solutions by notable margins of 0.47% and 0.74%, signifying a substantial enhancement in the image compression encoding efficiency. The results underscore the effectiveness of our approach in enhancing the capabilities of existing techniques, marking a significant step forward in the field of image compression.

Digital Library: JIST

FastTrack Article

47 5

Scratched Coating QR Code Image Restoration based on the Pluralistic Image Completion Deep Learning Method

QR Code
scratched coating QR Code image
image inpainting

Ao Zhu, Peng Cao

Pages 1 - 11, © Society for Imaging Science and Technology 2025

DOI

10.2352/J.ImagingSci.Technol.2025.69.3.030414

Abstract

In recent years, with the rapid development of digital printing technology, an increasing number of counterfeit products have entered the market. The anti-counterfeiting technique for QR Codes has been attracting increasing attention nowadays. There exist many image inpainting methods that can be applied in the image restoration field. Some image completion methods may restore coating QR Code images to a point where the covered digital number underneath is revealed even though the original coating QR Code has not been scratched off. In this paper, we extend the pluralistic image completion (PIC) method to scratched coating QR Code image restoration. Based on the binary characteristic of QR Codes, we present a specific type of deep learning model for scratched coating QR Code image completion. Experimental results demonstrate that the extended PIC is an effective approach to the restoration of scratched coating QR Code images.

Digital Library: JIST

FastTrack Article

Impact of Flight Altitude and Photo Control Points on the Accuracy of 2D and 3D Modeling in UAV Surveys: A Case Study of Jurong Dongshan River

42 8

UAV
oblique photography
water conveyance channel
water conservancy facilities

Hongfei Lu, Shan Yang, Hao Zhou, Jin Zhao, Fangfang Bai, Yang Han, Bo Zhen

Pages 1 - 15, © Society for Imaging Science and Technology 2025

DOI

10.2352/J.ImagingSci.Technol.2025.69.4.040506

CAPT 2024 Latest Innovations on Printing and Packaging Technologies

Abstract

Taking the Jurong Dongshan River as an illustrative case, we employed a Dajiang Phantom 4 RTK SE unmanned aerial vehicle (UAV) for single-lens tilt photography. Our investigation focused on examining the influence of varying flight altitudes (FA: 30 m, 60 m and 90 m) and the configuration of photo control points on two-dimentional (2D) or three-dimensional (3D) mapping accuracy of river embankments, slopes, and hydraulic structures, as well as the analysis of outcomes of 2D and 3D modeling under different FA conditions augmented with supplementary photographs. Our observations revealed that the longitude and elevation accuracy at 30 m FA were higher without photo control operations compared to those at 60 m and 90 m FA, and accuracy diminished as FA increased. Specifically, the longitude accuracy of the embankment photo control points exceeded that of the slope photo control points, whereas the elevation accuracy of the embankment photo control points was superior at FAs of 60 m and 90 m. The geographical location deviation of hydraulic structures (irrigation intake gates) in the 2D model was larger than that obtained in the 3D model. Notably, the incorporation of additional detailed photographs significantly augmented the modeling efficacy of UAV aerial survey data, especially in capturing intricate plant and slope details. It is recommended that the Phantom 4 RTK SE be used at FA of 90 m to establish a foundational channel model, along with capture of additional detailed photographs of crucial structures, slopes, etc., and obtaining geographic location information in 3D Models.

Digital Library: JIST

FastTrack Article

47 7

Improvement of Gas Barrier Properties and Antioxidant Activity of PVA/Hemicellulose Active Packaging Films Reinforced by Tea Polyphenols

hemicellulose
tea polyphenols
gas barrier
active packaging

Yonghang Niu, Yining Wang, Haonan Chen, Jian Du, Haisong Wang, Yanna Lv

DOI

10.2352/J.ImagingSci.Technol.2025.69.3.030407

Abstract

The preparation of active food packaging materials with both high gas barrier and antioxidant properties remains a great challenge. Hemicellulose is an abundant raw material with excellent oxygen barrier performance and biodegradability, and tea polyphenols (TPs) are natural antioxidants with the function of reducing water sensitivity of polysaccharide-based films. Herein, a synergistic strategy is reported for the preparation of active-controlled food packaging material by incorporating TP into the poly(vinyl alcohol) hemicellulose (PVA/HC) matrix. The obtained film with 5 wt% addition of TP exhibited the highest tensile strength of 41.09 MPa, which was increased by 84% than that of the PVA/HC film. Meanwhile, water vapor permeability was decreased by 25% to 7.39 × 10⁻¹² g⋅cm/(cm²⋅s⋅Pa) compared to a PVA/HC film. Moreover, the addition of TP improved the thermal stability of the (PVA/HC/TP)_n film. The outstanding packaging performances were attributed to the robust hydrogen bonding between TP and the PVA/HC matrix as demonstrated by Fourier transform infrared spectroscopy. The DPPH free radical scavenging of (PVA/HC/TP)₁₅ films reached 87.99%, and the film also exhibited enhanced inhibition efficiency against the microorganism E. coli. Compared with the polyethylene plastic wrap, the film showed excellent food packaging applicability by preventing air oxidation of fresh-cut potato. This study sheds light on a design strategy for active packaging films using a natural substance and easily available biomass.

Digital Library: JIST

FastTrack Article

Federated Learning for Image-based Cancer Detection and Diagnosis: A Systematic Review

41 5

cancer
computer-aided detection and diagnosis systems
deep learning
federated learning
privacy-preserving

Ye Jin, Jinshan Tang

DOI

10.2352/J.ImagingSci.Technol.2025.69.4.040502

CAPT 2024 Latest Innovations on Printing and Packaging Technologies

Abstract

Deep learning (DL) has advanced computer-aided diagnosis, yet the limited data available at local medical centers and privacy concerns associated with centralized AI approaches hinder collaboration. Federated learning (FL) offers a privacy-preserving solution by enabling distributed DL training across multiple medical centers without sharing raw data. This article reviews research conducted from 2016 to 2024 on the use of FL in cancer detection and diagnosis, aiming to provide an overview of the field’s development. Studies show that FL effectively addresses privacy concerns in DL training across centers. Future research should focus on tackling data heterogeneity and domain adaptation to enhance the robustness of FL in clinical settings. Improving the interpretability and privacy of FL is crucial for building trust. This review promotes FL adoption and continued research to advance cancer detection and diagnosis and improve patient outcomes.

Digital Library: JIST

FastTrack Article

36 6

Spectral Color Prediction based on Neugebauer Primary Colors and Improved PSO-DNN Model

printer characterization
spectral prediction model
principal component analysis
Neugebauer
deep neural network

Dongwen Tian, Junwei Qiao, Jinghuan Ge, Na Su

DOI

10.2352/J.ImagingSci.Technol.2025.69.3.030419

Abstract

Color accuracy in conventional and digital printing processes relies on press characterization to establish the relationship between input device values and output colorimetric or spectral reflectance values. Conventional models, such as Murray–Davies, Clapper–Yule, Yule–Nielsen, and Yule–Nielsen modified spectral Neugebauer, are renowned for providing accurate chromatic and spectral predictions. However, they fall short of accounting for the effects of black ink use and struggle to predict light hues accurately. In order to predict more accurately the color fingerprint, spectral reflectance, of halftone printed images, this study introduces a novel machine-learning-based deep neural network combined with the improved particle swarm optimization algorithm. This enables implementing a spectral reflectance color prediction model for CMYK printing, which eliminates the need to adjust for dot gain during printing. By evaluating this model on a lithographic offset press, we demonstrate its superior performance evidenced by significantly lower root mean square error and color difference (ΔE ∗ 00) values compared to existing methods. This approach minimizes color deviations during printing and reduces material and energy consumption, thereby ultimately enhancing the quality of printed materials.

Digital Library: JIST

FastTrack Article

Spectral Reflectance Reconstruction based on LED Light Sources

36 5

multi-spectral imaging system
spectral reflectance reconstruction
surface spectral reflectance
weighting coefficient

Chun Liang, Long Ma, Enliang Zhao

DOI

10.2352/J.ImagingSci.Technol.2025.69.2.020509