Fusion of Conventional and Deep Learning Methods for Offline Signature Verification

Authors

Dr Santhosh Kumar B N

Associate Professor, Department of Computer Science, Maharani’s Science College for Women (Autonomous), Mysore, Karnataka, India. (India)

Dr H S Nagalakshmi

Associate Professor and Head, Department of BCA, Government College for Women (Autonomous), Mandya, Karnataka, India. (India)

Dr Prakasha Raje Urs

Associate Professor, Department of Computer Science, Government First Grade College , Nanganagud, Karnataka, India. (India)

Article Information

DOI: 10.51584/IJRIAS.2026.11060056

Subject Category: Education

Volume/Issue: 11/6 | Page No: 588-592

Publication Timeline

Submitted: 2026-05-25

Accepted: 2026-05-30

Published: 2026-06-22

Abstract

Offline signature verification remains a critical yet challenging task in biometrics and forensic document analysis due to the complete lack of dynamic behavioral trajectories such as velocity, acceleration, and pen pressure. This paper presents a comprehensive study on the architectural paradigm that fuses conventional handcrafted feature-extraction techsniques with modern deep learning representation learning models. While conventional techniques like Histogram of Oriented Gradients (HOG) and Local Binary Patterns (LBP) robustly preserve exact geometric proportions and micro-textures, deep learning models like Convolutional Neural Networks (CNNs) capture highly complex, abstract structural representations. We systematically explore early feature-level fusion, late decision-level fusion, and hybrid metric learning pipelines. Our critical evaluation across benchmarks demonstrates that hybrid models dramatically mitigate the threat of skilled forgeries and generalize exceptionally well under constrained reference environments with limited training templates.

Keywords

Offline signature verification, feature fusion, Deep Learning, Siamese Networks, LBP, HOG, biometrics.

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References

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