Abstract
Feature fusion is a widely adopted strategy in multi-biometrics to enhance reliability, performance and real-world applicability. While combining multiple biometric sources can improve recognition accuracy, practical performance depends heavily on feature dependencies, redundancies, and selection methods. This study provides a comprehensive analysis of multimodal hand biometric recognition systems. We aim to guide the design of efficient, high-accuracy biometric systems by evaluating trade-offs between classical and learning-based approaches. For feature extraction, we employ Zernike moments and log-Gabor filters, evaluating multiple selection techniques to optimize performance. While baseline palmprint and fingerprint systems exhibit varying classification rates. Our feature fusion method achieves a consistent 99.29% identification rate across diverse classifiers. Additionally, we explore EfficientNET as an end-to-end feature extractor and classifier, comparing its fusion performance with the traditional approach. Our findings emphasize feature selection as the key of building efficient and stable recognition systems. Using the minimal optimal feature set, we achieve an equal error rate (EER) of 0.71%, demonstrating superior efficiency and accuracy.