TY - JOUR
T1 - Addressing Class Imbalance in X-ray Threat Detection with Self-Supervised Balanced DINO
AU - Belal, Mohammad
AU - Ahmed, Abdelfatah
AU - Velayudhan, Divya
AU - Hassan, Taimur
AU - Damiani, Ernesto
AU - Werghi, Naoufel
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - Aviation security, which is mainly tasked with the assurance of safety to the travelers by offering reliable baggage screening, remains a very critical issue. Traditional manual inspections are prone to errors and labor intensive. This calls for automatic detection systems. However, methods commonly used for X-ray threat detection have the problem of data imbalance and poor feature representation, especially for rare threat items. It proposes a novel Balanced DINO framework that incorporates the Focal-Augmented Loss to tackle the above challenges into a DINO-based Vision Transformer. Our study aims at balancing class representations, using both algorithmic weighting and data augmentation methods, to improve the detection accuracy of the rare threat items. Balanced DINO demonstrates extensive testing on three public datasets, namely SIXray, CLCXray, and COMPASS-XP, with considerably improved performance compared to state-of-the-art methods. Concrete, our framework outperforms the competitors by at most 3.77% in F1-score and at most 2.31%
AB - Aviation security, which is mainly tasked with the assurance of safety to the travelers by offering reliable baggage screening, remains a very critical issue. Traditional manual inspections are prone to errors and labor intensive. This calls for automatic detection systems. However, methods commonly used for X-ray threat detection have the problem of data imbalance and poor feature representation, especially for rare threat items. It proposes a novel Balanced DINO framework that incorporates the Focal-Augmented Loss to tackle the above challenges into a DINO-based Vision Transformer. Our study aims at balancing class representations, using both algorithmic weighting and data augmentation methods, to improve the detection accuracy of the rare threat items. Balanced DINO demonstrates extensive testing on three public datasets, namely SIXray, CLCXray, and COMPASS-XP, with considerably improved performance compared to state-of-the-art methods. Concrete, our framework outperforms the competitors by at most 3.77% in F1-score and at most 2.31%
KW - Focal-Augmented Loss
KW - Imbalanced Classification
KW - Threat Detection
KW - Vision Transformer
KW - X-ray Baggage Scan
UR - https://www.scopus.com/pages/publications/105001298776
U2 - 10.1109/ICEET65156.2024.10913663
DO - 10.1109/ICEET65156.2024.10913663
M3 - Conference article
AN - SCOPUS:105001298776
SN - 2409-2983
JO - International Conference on Engineering and Emerging Technologies, ICEET
JF - International Conference on Engineering and Emerging Technologies, ICEET
IS - 2024
T2 - 10th International Conference on Engineering and Emerging Technologies, ICEET 2024
Y2 - 27 December 2024 through 28 December 2024
ER -