The SUCI-AKA Authentication Protocol for 5G Systems

Security is a fundamental requirement for all digital systems. In this paper we propose a new entity authentication protocol, which we call the SUCI-AKA protocol. In contrast to the existing 5G-AKA protocol, it will provide online mutual entity authentication. A central design criteria has been to provide a solution which minimizes the system impact and avoids hard breaks with existing schemes. The SUCI-AKA protocol is largely based on the new 5G scheme for subscriber privacy, and integrates it with the existing 5G-AKA entity authentication protocol in a novel way. This provides scope for accommodating both credible subscriber privacy and online mutual entity authentication

Development of Secure Mobile Cloud Computing Using Improved Identity Management Protocol

The convergence of Internet and mobile computing enables personalized access to online services anywhere and anytime. Entities (e.g., users , services) have to authenticate themselves to service providers in order to use their services. An entity provides personally identifiable information that uniquely identifies it to an SP. Due to the rapid spread of smart phones and social network service, the use of Interne applications has increased and their need for bandwidth has begun to exceed the capacity of 3G networks. This has caused a re duction in speed and service quality. The increase in mobile network users has caused identity management probl ems for mobile service providers. Therefore, in this paper, proposed system is designed t o overcome this problem Improved Identity Management protocol is used to breaks up loads, which are allowed by the existing Identity Management 3G protocols mutual authentication via mobile operator process, by sending some parts to an Internet application service provider to enhance mobile and ID management at the service provider and by reducing the network and process loads from information handling and packet trans mission

Security on Medical Wireless Sensor Networks

Wireless technology is fast becoming a very important tool for all aspects of communication. An area that lacks a strong implementation for wireless communication is the medical field. Wireless systems could be used by clinicians to be better able to diagnose and monitor patients. The reason behind the lack of adoption in healthcare is due to the need to meet the legislated and perceived requirements of security and privacy when dealing with clinical information. The current methods of wireless authentication are investigated and an existing issue in mobile networks is described and solved with two novel solutions; one solution within GSM and the other within UMTS. Strong authentication protocols are developed based on the existing wireless protocols, while using minimal messages and symmetric operations to limit resource utilization to meet the needs of the healthcare environment. To ensure the quality of the protocol a BAN (Burrows-Abadi-Needham logic) analysis is performed which verifies that the desired goals of the protocols are appropriately met within the results analysis. The developed security protocol is shown to be secure, uses minimal messages to maintain efficiency and meets the legal requirements to be used in medical wireless sensor networks

Retrofitting Mutual Authentication to GSM Using RAND Hijacking

As has been widely discussed, the GSM mobile telephony system only offers unilateral authentication of the mobile phone to the network; this limitation permits a range of attacks. While adding support for mutual authentication would be highly beneficial, changing the way GSM serving networks operate is not practical. This paper proposes a novel modification to the relationship between a Subscriber Identity Module (SIM) and its home network which allows mutual authentication without changing any of the existing mobile infrastructure, including the phones; the only necessary changes are to the authentication centres and the SIMs. This enhancement, which could be deployed piecemeal in a completely transparent way, not only addresses a number of serious vulnerabilities in GSM but is also the first proposal for enhancing GSM authentication that possesses such transparency properties.Comment: 17 pages, 2 figure

UMTS broadband mobile technology is a reality – Confounding many expectations

Contrary to the negative public perception, third-generation (3G) broadband mobile telecommunication, aka UMTS, has become reality. UMTS networks have been rolled out above all in Central Europe. The take-up of UMTS differs sharply from one country to the next, though. The large differences are due not only to market-related factors and differing marketing strategies, but also to political intervention that distorts the market. At present, content providers, handset makers and telcos are working feverishly to produce UMTS-based supplementary offerings. For the sluggish demand for mobile broadband services still harbours a big risk for the entire telecommunications sector.information an communications technology; telecommunications; 3G; broadband

Securing Handover in Wireless IP Networks

In wireless and mobile networks, handover is a complex process that involves multiple layers of protocol and security executions. With the growing popularity of real time communication services such as Voice of IP, a great challenge faced by handover nowadays comes from the impact of security implementations that can cause performance degradation especially for mobile devices with limited resources. Given the existing networks with heterogeneous wireless access technologies, one essential research question that needs be addressed is how to achieve a balance between security and performance during the handover. The variations of security policy and agreement among different services and network vendors make the topic challenging even more, due to the involvement of commercial and social factors. In order to understand the problems and challenges in this field, we study the properties of handover as well as state of the art security schemes to assist handover in wireless IP networks. Based on our analysis, we define a two-phase model to identify the key procedures of handover security in wireless and mobile networks. Through the model we analyze the performance impact from existing security schemes in terms of handover completion time, throughput, and Quality of Services (QoS). As our endeavor of seeking a balance between handover security and performance, we propose the local administrative domain as a security enhanced localized domain to promote the handover performance. To evaluate the performance improvement in local administrative domain, we implement the security protocols adopted by our proposal in the ns-2 simulation environment and analyze the measurement results based on our simulation test

Privacy Enhanced Fast Mutual Authentication in 5G Network Using Identity Based Encryption

Subscription privacy of a user has been a historical concern with all the previous generation mobile networks, namely, GSM, UMTS, and LTE. While a little improvement have been achieved in securing the privacy of the long-term identity of a subscriber, the so called IMSI catchers are still in existence even in the LTE and advanced LTE networks. Proposals have been published to tackle this problem in 5G based on pseudonyms, and different public-key technologies. This paper looks into the problem of concealing long-term identity of a subscriber and presents a protocol based on identity based encryption (IBE) to tackle it. The proposed solution can be extended to a mutual authentication and key agreement protocol between a serving network (SN) and a user equipment (UE). We name the protocol PEFMA (privacy enhanced fast mutual authentication). The SN does not need to connect with the home network (HN) on every PEFMA run. In PEFMA, both the user equipment (UE) and the SN has public keys. A UE sends the IMSI after encrypting it using the SN’s public key. Since both the UE and SN have public keys, PEFMA can run without contacting the HN. A qualitative comparison of different techniques show that our solution is competitive for securing the long-term identity privacy of a user in the 5G network.Peer reviewe