Biometric recognition offers a reliable solution to the problem of user authentication in identity management systems. With the widespread deployment of biometric systems in various applications, there are increasing concerns about the security and privacy of biometric technology. Public acceptance of biometrics technology will depend on the ability of system designers to demonstrate that these systems are robust, have low error rates, and are tamper proof. We present a high-level categorization of the various vulnerabilities of a biometric system and discuss countermeasures that have been proposed to address these vulnerabilities. In particular, we focus on biometric template security which is an important issue because, unlike passwords and tokens, compromised biometric templates cannot be revoked and reissued. Protecting the template is a challenging task due to intrauser variability in the acquired biometric traits. We present an overview of various biometric template protection schemes and discuss their advantages and limitations in terms of security, revocability, and impact on matching accuracy. A template protection scheme with provable security and acceptable recognition performance has thus far remained elusive. Development of such a scheme is crucial as biometric systems are beginning to proliferate into the core physical and information infrastructure of our society.

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Biometric template security

With the development of the Internet, cyber-attacks are changing rapidly and the cyber security situation is not optimistic. This survey report describes key literature surveys on machine learning (ML) and deep learning (DL) methods for network analysis of intrusion detection and provides a brief tutorial description of each ML/DL method. Papers representing each method were indexed, read, and summarized based on their temporal or thermal correlations. Because data are so important in ML/DL methods, we describe some of the commonly used network datasets used in ML/DL, discuss the challenges of using ML/DL for cybersecurity and provide suggestions for research directions.

Machine Learning and Deep Learning Methods for Cybersecurity

Form a privacy perspective most concerns against the common use of biometrics arise from the storage and misuse of biometric data. Biometric cryptosystems and cancelable biometrics represent emerging technologies of biometric template protection addressing these concerns and improving public confidence and acceptance of biometrics. In addition, biometric cryptosystems provide mechanisms for biometric-dependent key-release. In the last years a significant amount of approaches to both technologies have been published. A comprehensive survey of biometric cryptosystems and cancelable biometrics is presented. State-of-the-art approaches are reviewed based on which an in-depth discussion and an outlook to future prospects are given.

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A survey on biometric cryptosystems and cancelable biometrics

Reliable information security mechanisms are required to combat the rising magnitude of identity theft in our society. While cryptography is a powerful tool to achieve information security, one of the main challenges in cryptosystems is to maintain the secrecy of the cryptographic keys. Though biometric authentication can be used to ensure that only the legitimate user has access to the secret keys, a biometric system itself is vulnerable to a number of threats. A critical issue in biometric systems is to protect the template of a user which is typically stored in a database or a smart card. The fuzzy vault construct is a biometric cryptosystem that secures both the secret key and the biometric template by binding them within a cryptographic framework. We present a fully automatic implementation of the fuzzy vault scheme based on fingerprint minutiae. Since the fuzzy vault stores only a transformed version of the template, aligning the query fingerprint with the template is a challenging task. We extract high curvature points derived from the fingerprint orientation field and use them as helper data to align the template and query minutiae. The helper data itself do not leak any information about the minutiae template, yet contain sufficient information to align the template and query fingerprints accurately. Further, we apply a minutiae matcher during decoding to account for nonlinear distortion and this leads to significant improvement in the genuine accept rate. We demonstrate the performance of the vault implementation on two different fingerprint databases. We also show that performance improvement can be achieved by using multiple fingerprint impressions during enrollment and verification.

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Fingerprint-Based Fuzzy Vault: Implementation and Performance

Biometric analysis for identity verification is becoming a widespread reality. Such implementations necessitate large-scale capture and storage of biometric data, which raises serious issues in terms of data privacy and (if such data is compromised) identity theft. These problems stem from the essential permanence of biometric data, which (unlike secret passwords or physical tokens) cannot be refreshed or reissued if compromised. Our previously presented biometric-hash framework prescribes the integration of external (password or token-derived) randomness with user-specific biometrics, resulting in bitstring outputs with security characteristics (i.e., noninvertibility) comparable to cryptographic ciphers or hashes. The resultant BioHashes are hence cancellable, i.e., straightforwardly revoked and reissued (via refreshed password or reissued token) if compromised. BioHashing furthermore enhances recognition effectiveness, which is explained in this paper as arising from the random multispace quantization (RMQ) of biometric and external random inputs

Random Multispace Quantization as an Analytic Mechanism for BioHashing of Biometric and Random Identity Inputs

Biometrics-based user authentication has several advantages over traditional password-based systems for standalone authentication applications. This is also true for new authentication architectures known as crypto-biometric systems, where cryptography and biometrics are merged to achieve high security and user convenience at the same time. Recently, a cryptographic construct, called fuzzy vault, has been proposed for crypto-biometric systems. This construct aims to secure critical data(e.g., secret encryption key) with the fingerprint data in a way that only the authorized user can access the secret by providing the valid fingerprint, and some implementations results for fingerprint have been reported. However, all the previous results assumed that fingerprint features were pre-aligned, and automatic alignment in the fuzzy vault domain is a challenging issue. In this paper, we perform the automatic alignment of fingerprint features by using the geometric hashing technique which has been used for model-based object recognition applications. Based on the preliminary experimental results, we confirm that the proposed approach can align fingerprint features automatically in the domain of the fuzzy vault and can be integrated with any fuzzy fingerprint vault systems.

Automatic alignment of fingerprint features for fuzzy fingerprint vault

Due to rapid growth of communications and networks, a cyber-attack with malicious codes has been coming as a new paradigm in information security area since last few years. In particular, an advanced persistent threats (APT) attack is bringing out big social issues. The APT attack uses social engineering methods to target various systems for intrusions. It breaks down the security of the target system to leak information or to destroy the system by giving monetary damages on the target. APT attacks make relatively simple attacks such as spear phishing during initial intrusion but a back door is created by leaking the long-term information after initial intrusion, and it transmits the malicious code by analyzing the internal network. In this paper, we propose an intrusion detection system based on the decision tree using analysis of behavior information to detect APT attacks that intellectually change after intrusion into a system. Furthermore, it can detect the possibility on the initial intrusion and minimize the damage size by quickly responding to APT attacks.

DTB-IDS: an intrusion detection system based on decision tree using behavior analysis for preventing APT attacks

Recently in the connected digital world, targeted attack has become one of the most serious threats to conventional computing systems. Advanced persistent threat (APT) is currently one of the most important threats considering the information security concept. APT persistently collects data from a specific target by exploiting vulnerabilities using diverse attack techniques. Many researchers have contributed to find approaches and solutions to fight against network intrusion and malicious software. However, only a few of these solutions are particularly focused on APT. In this paper, we introduce a structured study on semantic-aware work to find potential contributions that analyze and detect APT in details. We propose modeling phase that discusses the typical steps in APT attacks to collect the desired information by attackers. Our research explores social network and web infrastructure exploitation as well as communication protocols and much more for future networks and communications. The paper also includes some recent Zero-day attacks, use case scenarios and cyber trends in southeastern countries. To overcome these challenges and attacks, we introduce a detailed comprehensive literature evaluation scheme that classifies and provides countermeasures of APT attack behavior. Furthermore, we discuss future research direction of APT defense framework of next-generation threat life cycle.

A comprehensive study on APT attacks and countermeasures for future networks and communications: challenges and solutions

Recently, Ratha and others proposed a cancelable biometrics scheme which transforms an original fingerprint template into a new one using a noninvertible transformation. However, we show that the original template is recovered by a dictionary attack if two transformed templates originating from it are revealed. In our attack, we simulate the transformation and construct a set of possible pre-images for each transformed template. Then, we find the correct pre- image by computing the intersection of these sets. We present an algorithm implementing this idea as well as successful experimental results.

Dictionary Attack on Functional Transform-Based Cancelable Fingerprint Templates

Biometric-based authentication can provide a strong security guarantee of the identity of users. However, the security of biometric data is particularly important as any compromise of the biometric data will be permanent. In this paper, we propose a secure and efficient protocol to transmit fingerprint images from a fingerprint sensor to a client by exploiting the characteristics of the fingerprint images. Because the fingerprint sensor is computationally limited, a standard encryption algorithm may not be applied to the full fingerprint images in real-time to guarantee the integrity and confidentiality of the fingerprint images transmitted. To reduce the computational workload on the resource-constrained sensor, we apply the encryption algorithm to a nonce for integrity and to a specific bitplane of each pixel of the fingerprint image for confidentiality. Experimental results show that the integrity and confidentiality of the fingerprint images can be guaranteed without any leakage of the fingerprint ridge information and can be completed in real-time on embedded processors.

Daesung Moon

Papers

Automatic alignment of fingerprint features for fuzzy fingerprint vault

DTB-IDS: an intrusion detection system based on decision tree using behavior analysis for preventing APT attacks

A comprehensive study on APT attacks and countermeasures for future networks and communications: challenges and solutions

Dictionary Attack on Functional Transform-Based Cancelable Fingerprint Templates

An Efficient Selective Encryption of Fingerprint Images for Embedded Processors