Mutual Information Based Feature Selection for Fingerprint Identification

Ahlem Adjimi,Messaoud Mostefai,Abdenour Hacine-Gharbi,Philippe Ravier

doi:10.31449/inf.v43i2.1621

Abstract

In the field of fingerprint identification, local histograms coding is one of the most popular techniques used for fingerprint representation, due to its simplicity. This technique is based on the concatenation of the local histograms resulting in a high dimension histogram, which causes two problems. First, long computing time and big memory capacities are required with databases growing. Second, the recognition rate may be degraded due to the curse of dimensionality phenomenon. In order to resolve these problems, we propose to reduce the dimensionality of histograms by choosing only the pertinent bins from them using a feature selection approach based on the mutual information computation. For fingerprint features extraction we use four descriptors: Local Binary Patterns (LBP), Histogram of Gradients (HoG), Local Phase Quantization (LPQ) and Binarized Statistical Image Features (BSIF). As mutual information based selection methods, we use four strategies: Maximization of Mutual Information (MIFS), minimum Redundancy and Maximal Relevance (mRMR), Conditional Info max Feature Extraction (CIFE) and Joint Mutual Information (JMI). We compare results in terms of recognition rates and number of selected features for the investigated descriptors and selection strategies. Our results are conducted on the four FVC 2002 datasets which present different image qualities. We show that the combination of mRMR or CIFE feature selection methods with HoG features gives the best results. We also show that the selection of useful fingerprint features can surely improve the recognition rate and reduce the complexity of the system in terms of computation cost. The feature selection algorithms may reach 98% of time reduction by considering only 20% of the total number of features while also improving the recognition rate of about 2% by avoiding the curse of dimensionality phenomena.

Highlights

Biometric recognition has gained a considerable interest in the recent years because of the various applications in the large field of security
We extend the fingerprint recognition system proposed in [23] by considering more datasets within the FVC2002 fingerprint database, more descriptor types and by investigating several other feature selection strategies, all based on mutual information computation to select the relevant bins of histograms that are extracted from the fingerprint images
It can be concluded that the Histogram of Gradients (HoG) and Local Phase Quantization (LPQ) descriptors are robust with respect to the dataset diversity because of general high recognition rates compared to the other descriptors

Summary

Introduction

Biometric recognition has gained a considerable interest in the recent years because of the various applications in the large field of security. Fingerprint recognition systems can be categorized into three main approaches: minutiae-based systems, imagebased correlation systems and image-based distance systems [2]. The fingerprint image must pass through several preprocessing steps to detect and extract some points of interest called minutiae: smoothing, local ridge orientation estimation, binarization, thinning, and minutia detection. Global or local features are extracted from the fingerprint image such that the features called descriptors retain most of the pertinent information representing the fingerprint.

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