A robust ElGamal‐based password‐authentication protocol using smart card for client‐server communication

Smart card‐based client‐server authentication protocol is well popular for secure data exchange over insecure and hostile networks. Recently, Lee et al. put forward an authentication protocol by utilizing ElGamal cryptosystem and proved that it can withstand known security threats. This article evinces that the protocol of Lee et al. is unwilling to protect various important security vulnerabilities such as forgery attack and off‐line password‐guessing attack. To vanquish these loopholes, this article presents a robust authentication protocol for client‐server communication over any insecure networks. The security explanation of our protocol has done through the formal and informal mechanism and its outcome makes sure that the designed protocol is strong enough to resist the known vulnerabilities. In addition, we have simulated our protocol using ProVerif online software and its results certify that our protocol is safe against private information of the client and server. This paper also has made performance estimation of the presented protocol and others, and the outcome favors the presented protocol.     

Cryptanalysis of smart‐card‐based password authenticated key agreement protocol for session initiation protocol of Zhang et al.

As the core signaling protocol for multimedia services, such as voice over internet protocol, the session initiation protocol (SIP) is receiving much attention and its security is becoming increasingly important. It is critical to develop a roust user authentication protocol for SIP. The original authentication protocol is not strong enough to provide acceptable security level, and a number of authentication protocols have been proposed to strengthen the security. Recently, Zhang et al. proposed an efficient and flexible smart‐card‐based password authenticated key agreement protocol for SIP. They claimed that the protocol enjoys many unique properties and can withstand various attacks. However, we demonstrate that the scheme by Zhang et al. is insecure against the malicious insider impersonation attack. Specifically, a malicious user can impersonate other users registered with the same server. We also proposed an effective fix to remedy the flaw, which remedies the security flaw without sacrificing the efficiency. The lesson learned is that the authenticators must be closely coupled with the identity, and we should prevent the identity from being separated from the authenticators in the future design of two‐factor authentication protocols. Copyright © 2014 John Wiley & Sons, Ltd.     

A lightweight anonymous two‐factor authentication protocol for wireless sensor networks in Internet of Vehicles

Internet of Vehicles (IoV), as the next generation of transportation systems, tries to make highway and public transportation more secure than used to be. In this system, users use public channels for their communication so they can be the victims of passive or active attacks. Therefore, a secure authentication protocol is essential for IoV; consequently, many protocols are presented to provide secure authentication for IoV. In 2018, Yu et al proposed a secure authentication protocol for WSNs in vehicular communications and claimed that their protocol could satisfy all crucial security features of a secure authentication protocol. Unfortunately, we found that their protocol is susceptible to sensor capture attack, user traceability attack, user impersonation attack, and offline sink node's secret key guessing attack. In this paper, we propose a new authentication protocol for IoV which can solve the weaknesses of Yu et al's protocol. Our protocol not only provides anonymous user registration phase and revocation smart card phase but also uses the biometric template in place of the password. We use both Burrow‐Abadi‐Needham (BAN) logic and real‐or‐random (ROR) model to present the formal analysis of our protocol. Finally, we compare our protocol with other existing related protocols in terms of security features and computation overhead. The results prove that our protocol can provide more security features and it is usable for IoV system.     

Revised anonymous authentication protocol for adaptive client‐server infrastructure

Rapid evolution in information and communication technologies has facilitated us to experience mobile communication in our daily routine. Mobile user can only avail the services from the server, once he/she is able to accomplish authentication process successfully. In the recent past, several researchers have contributed diverse authentication protocols for mobile client‐server environment. Currently, Lu et al designed two‐factor protocol for authenticating mobile client and server to exchange key between them. Lu et al emphasized that their scheme not only offers invincibility against potential security threats but also offers anonymity. Although this article reveals the facts that their protocol is vulnerable against client and server impersonation, man‐in‐the‐middle, server key breach, anonymity violation, client traceability, and session‐specific temporary attacks, therefore, we have enhanced their protocol to mitigate the above mention vulnerabilities. The enhanced protocol's security strength is evaluated through formal and informal security analysis. The security analysis and performance comparison endorses the fact that our protocol is able to offer more security with least possible computation complexity.     

A secure and efficient identity‐based mutual authentication scheme with smart card using elliptic curve cryptography

The e‐commerce has got great development in the past decades and brings great convenience to people. Users can obtain all kinds of services through e‐commerce platform with mobile device from anywhere and at anytime. To make it work well, e‐commerce platform must be secure and provide privacy preserving. To achieve this goal, Islam et al. proposed a dynamic identity‐based remote user mutual authentication scheme with smart card using Elliptic Curve Cryptography(ECC). Islam et al claimed that the security of their scheme was good enough to resist various attacks. However, we demonstrate that their scheme is vulnerable to insider attack and suffers from off‐line password guessing attack if smart card is compromised. To overcome the deficiencies, we present an improved scheme over Islam's scheme. The security proof and analysis shows that our scheme can also provide user anonymity and mutual authentication, and the security is enough to against relay attack, impersonation attack, and other common secure attackers. The performance analysis shows that the proposed scheme is more efficient than Islam et al's scheme.     

An Improved RFID Authentication Protocol Based on Group Anonymous Model

Aiming at the security and privacy, and authentication efficiency shortages of existing RFID authentication protocol, an improved scheme is proposed based on Alavi et al.’s protocol. Firstly, in order to resist against replay attack, we add the timestamp generator to the reader side and use hash function to encrypt the reader identification, the random number and timestamp generated by the reader; meanwhile, to solve the data integrity problem in the original scheme, the reader matches the decrypted data with the server side message to ensure that it can detect if the data is tampered with by the attacker. Finally, the improved group anonymous authentication model is used to improve the back-end server’s authentication efficiency. Theoretical analysis and experimental results show that the improved protocol effectively solves the security problems and reduces the back-end server’s authentication time. In addition, this paper simulates the impact of group number on system privacy level and authentication efficiency through experiments. In practical applications, the group number can be adjusted appropriately according to different privacy and efficiency requirements, so the privacy and authentication efficiency of the system will be well-balanced.     

On the security and improvement of privacy‐preserving 3‐factor authentication scheme for TMIS

The telecare medicine information system (TMIS) enables patients from different regions to remotely share the same telecare services, which significantly enhances the quality and effectiveness of medical treatment. On the other hand, patients' electronic health records usually involve their privacy information, they thus hesitate to directly transmit these information in TMIS over the public network due to the threat of privacy disclosure. The authenticated key agreement, as a core building of securing communications over the public network, is considered to be necessary for strengthening the security of TMIS. Recently, we note Zhang et al introduced a 3‐factor authenticated key agreement scheme for TMIS and asserted that the proposed scheme can resist various well‐known attacks. Unfortunately, in this paper, we point out that the scheme of Zhang et al cannot achieve the claimed security guarantees. Specifically, their scheme is vulnerable to offline password/identity guessing attack and user/server impersonation attack. To conquer the above security pitfalls, we put forward a new 3‐factor authenticated key agreement scheme with privacy preservation for TMIS. The security evaluation and performance discussion indicate that our scheme can be free from those well‐known and classical attacks including offline guessing attack and impersonation attack, without increasing additional computation cost when compared with related works. Consequently, the new authentication scheme would be more desirable for securing communications in TMIS.     

Security and Privacy Analysis of Song–Mitchell RFID Authentication Protocol

Many applications, such as e-passport, e-health, credit cards, and personal devices that utilize Radio frequency Identification (RFID) devices for authentication require strict security and privacy. However, RFID tags suffer from some inherent weaknesses due to restricted hardware capabilities and are vulnerable to eavesdropping, interception, or modification. The synchronization and untraceability characteristics are the major determinants of RFID authentication protocols. They are strongly related to privacy of tags and availability, respectively. In this paper, we analyze a new lightweight RFID authentication protocol, Song and Mitchell, in terms of privacy and security. We prove that not only is the scheme vulnerable to desynchronization attack, but it suffers from traceability and backward traceability as well. Finally, our improved scheme is proposed which can prevent aforementioned attacks.     

An Enhanced Authentication Scheme with Privacy Preservation for Roaming Service in Global Mobility Networks

Global mobility network (GLOMONET) provides global roaming service to ensure ubiquitous connectivity for users traveling from one network to another. It is very crucial not only to authenticate roaming users, but to protect the privacy of users. However, due to the broadcast nature of wireless channel and resource limitations of terminals, providing efficient user authentication with privacy preservation is challenging. Recently, He et al. proposed a secure and lightweight user authentication scheme with anonymity for roaming service in GLOMONETs. However, in this paper, we identify that the scheme fails to achieve strong two-factor security, and suffers from domino effect, privileged insider attack and no password change option, etc. Then we propose an enhanced authentication scheme with privacy preservation based on quadratic residue assumption. Our improved scheme enhances security strength of He et al.’s protocol while inheriting its merits of low communication and computation cost. Specifically, our enhanced scheme achieves two-factor security and user untraceability.     

An anonymous and untraceable password‐based authentication scheme for session initiation protocol using smart cards

Recently, Zhang et al. proposed a password‐based authenticated key agreement for session initiation protocol (Int J Commun Syst 2013, doi:10.1002/dac.2499). They claimed that their protocol is secure against known security attacks. However, in this paper, we indicate that the protocol by Zhang et al. is vulnerable to impersonation attack whereby an active adversary without knowing the user's password is able to introduce himself/herself as the user. In addition, we show that the protocol by Zhang et al. suffers from password changing attack. To overcome the weaknesses, we propose an improved authentication scheme for session initiation protocol. The rigorous analysis shows that our scheme achieves more security than the scheme by Zhang et al. Copyright © 2014 John Wiley & Sons, Ltd.     

An efficient chaos‐based 2‐party key agreement protocol with provable security

Key agreement protocol is an important cryptographic primitive, which allows 2 parties to establish a secure session in an open network environment. A various of key agreement protocols were proposed. Nowadays, there still exists some other security flaws waiting to be solved. Owing to reduce the computational and communication costs and improve the security, chaotic map has been studied in‐depth and treated as a good solution. Recently, Liu et al proposed a chaos‐based 2‐party key agreement protocol and demonstrated that it can defend denial‐of‐service attack and replay attack. We found, however, it cannot resist off‐line password‐guessing attack, and it also has some other security flaws. In this paper, we propose an improved chaos‐based 2‐party key agreement protocol. The results prove that the protocol can solve the threats of off‐line password‐guessing attack and other security flaws in the security proof section. What is more, performance analysis shows that the computational cost of the improved protocol is lower than Liu et al protocol.     

A Secure and Effective Anonymous User Authentication Scheme for Roaming Service in Global Mobility Networks

In global mobility networks, anonymous user authentication is an essential task for enabling roaming service. In a recent paper, Jiang et al. proposed a smart card based anonymous user authentication scheme for roaming service in global mobility networks. This scheme can protect user privacy and is believed to have many abilities to resist a range of network attacks, even if the secret information stored in the smart card is compromised. In this paper, we analyze the security of Jiang et al.’s scheme, and show that the scheme is in fact insecure against the stolen-verifier attack and replay attack. Then, we also propose a new smart card based anonymous user authentication scheme for roaming service. Compared with the existing schemes, our protocol uses a different user authentication mechanism, which does not require the home agent to share a static secret key with the foreign agent, and hence, it is more practical and realistic. We show that our proposed scheme can provide stronger security than previous protocols.     

On the Security of “Secure and Lightweight Authentication with Key Agreement for Smart Wearable Systems”

Over the years, the performance of devices used to gather sensitive medical information about individuals has increased substantially. These include implanted devices in the body, placed on or around the body, creating a Wireless body area network. Security and privacy have been a greater concern over a period of time due to the sensitive nature of the data collected and transmitted by the network. It has been noticed that various techniques have been applied to secure the data and provide privacy in WBANs but with a tradeoff of execution overhead. Although the latest available anonymous authentication schemes provide privacy and security but due to the limited computation capacity of WBAN devices, these schemes show greater time cost for authentication and consume more processing time. We review two latest anonymous authentication schemes for the WBAN environment in terms of computation cost. These two schemes provide anonymous authentication and use encryption to secure the data and ensure privacy. Then we analyze a recent lightweight authentication scheme proposed for wearable devices which provides anonymity and privacy along with security with very low computation cost. This scheme uses hash functions in order to obtain authentication and anonymity and doesn’t use encryption in the authentication process. This scheme is not proposed for the WBAN environment, but it can be applied on the WBAN environment with necessary variations. The comparison of these available schemes shows clearly that the computation cost is considerably decreased by applying the latest authentication scheme in the WBAN environment. We propose a new authentication scheme for the WBAN environment based on the light-weight scheme proposed for wearable devices. The detailed analysis shows that our proposed scheme minimizes the computation cost and maintains the privacy and security along with anonymous authentication.

     

A pairing‐free identity‐based handover AKE protocol with anonymity in the heterogeneous wireless networks

Nowadays, seamless roaming service in heterogeneous wireless networks attracts more and more attention. When a mobile user roams into a foreign domain, the process of secure handover authentication and key exchange (AKE) plays an important role to verify the authenticity and establish a secure communication between the user and the access point. Meanwhile, to prevent the user's current location and moving history information from being tracked, privacy preservation should be also considered. However, existing handover AKE schemes have more or less defects in security aspects or efficiency. In this paper, a secure pairing‐free identity‐based handover AKE protocol with privacy preservation is proposed. In our scheme, users' temporary identities will be used to conceal their real identities during the handover process, and the foreign server can verify the legitimacy of the user with the home server's assistance. Besides, to resist ephemeral private key leakage attack, the session key is generated from the static private keys and the ephemeral private keys together. Security analysis shows that our protocol is provably secure in extended Canetti‐Krawczyk (eCK) model under the computational Diffie‐Hellman (CDH) assumption and can capture desirable security properties including key‐compromise impersonation resistance, ephemeral secrets reveal resistance, strong anonymity, etc. Furthermore, the efficiency of our identity‐based protocol is improved by removing pairings, which not only simplifies the complex management of public key infrastructure (PKI) but also reduces the computation overhead of ID‐based cryptosystem with pairings. It is shown that our proposed handover AKE protocol provides better security assurance and higher computational efficiency for roaming authentication in heterogeneous wireless networks.     

Provable analysis and improvement of smart card–based anonymous authentication protocols

Nowadays, authentication protocols are essential for secure communications specially for roaming networks, distributed computer networks, and remote wireless communication. The numerous users in these networks rise vulnerabilities. Thus, privacy‐preserving methods have to be run to provide more reliable services and sustain privacy. Anonymous authentication is a method to remotely authenticate users with no revelation about their identity. In this paper, we analyze 2 smart card–based protocols that the user's identity is anonymous. However, we represent that they are vulnerable to privileged insider attack. It means that the servers can compromise the users' identity for breaking their privacy. Also, we highlight that the Wen et al protocol has flaws in both stolen smart card and stolen server attacks and the Odelu et al protocol is traceable. Then, we propose 2 modified anonymous authentication protocols. Finally, we analyze our improved protocols with both heuristic and formal methods.     

An Efficient Ticket Based Authentication Protocol with Unlinkability for Wireless Access Networks

The concept of anonymous channel ticket is one of the effective measures to protect user privacy and to reduce the overhead of re-authentication for wireless environments. Most recently, Hsieh et al. proposed an anonymous authentication protocol based on elliptic curve cryptography to enhance the efficiency and security strength. However, we identify that Hsieh et al.’s scheme has four weaknesses. (1) The scheme fails to provide identity anonymity. (2) The ticket authentication phase of the scheme suffers from desynchronization attack. (3) The scheme is vulnerable to the privileged insider attack. (4) Users cannot change passwords when required. We further propose an improved authentication scheme, which not only preserves the merits of the scheme of Hsieh et al., but also enjoys several other advantages. Our improved scheme is effective in protection from the weaknesses identified and achieves user anonymity and unlinkability. We compare the functionality and performance of our improved scheme with other related schemes, which indicates that our scheme is more secure and yet efficient for wireless access networks.     

An Improved User Authentication and Key Agreement Scheme Providing User Anonymity

When accessing remote services over public networks, a user authentication mechanism is required because these activities are executed in an insecure communication environment. Recently, Wang et al. proposed an authentication and key agreement scheme preserving the privacy of secret keys and providing user anonymity. Later, Chang et al. indicated that their scheme suffers from two security flaws. First, it cannot resist DoS (denial-of-service) attack because the indicators for the next session are not consistent. Second, the user password may be modified by a malicious attacker because no authentication mechanism is applied before the user password is updated. To eliminate the security flaws and preserve the advantages of Wang et al.'s scheme, we propose an improvement in this paper.     

An efficient remote user authentication and key agreement protocol for mobile client–server environment from pairings

With the continue evaluation of mobile devices in terms of the capabilities and services, security concerns increase dramatically. To provide secured communication in mobile client–server environment, many user authentication protocols from pairings have been proposed. In 2009, Goriparthi et al. proposed a new user authentication scheme for mobile client–server environment. In 2010, Wu et al. demonstrated that Goriparthi et al.’s protocol fails to provide mutual authentication and key agreement between the client and the server. To improve security, Wu et al. proposed an improved protocol and demonstrated that their protocol is provably secure in random oracle model. Based on Wu et al.’s work, Yoon et al. proposed another scheme to improve performance. However, their scheme just reduces one hash function operation at the both of client side and the server side. In this paper, we present a new user authentication and key agreement protocol using bilinear pairings for mobile client–server environment. Performance analysis shows that our protocol has better performance than Wu et al.’s protocol and Yoon et al.’s protocol. Then our protocol is more suited for mobile client–server environment. Security analysis is also given to demonstrate that our proposed protocol is provably secure against previous attacks.