A New Secure Authentication Protocol for Telecare Medicine Information System and Smart Campus

© 2013 IEEE. Telecare Medicine Information System (TMIS)'s security importance attracts a lot of attention these days. Whatever the security of TMIS improves, its application becomes wider. To address this requirement, recently, Li et al. proposed a new privacy-preserving RFID authentication protocol for TMIS. After that, Zhou et al. and also Benssalah et al. presented their scheme, which is not secure, and they presented their new authentication protocol and claim that their proposal can provide higher security for TMIS applications. In this stream, Zheng et al. proposed a novel authentication protocol with application in smart campus, including TMIS. In this paper, we present an efficient impersonation and replay attacks against Zheng et al. with the success probability of 1 and a desynchronization attack which is applicable against all of the rest three mentioned protocols with the success probability of 1-2^{-n} , where n is the protocols parameters length. After that, we proposed a new protocol despite these protocols can resist the attacks presented in this paper and also other active and passive attacks. Our proposed protocol's security is also done both informally and formally through the Scyther tool

A Secure Authentication Scheme for RFID Systems

AbstractDay by day the importance of Radio Frequency Identification (RFID) systems is increasing for its powerful capabilities in automatic identification, localization and access control of the objects. However, the RFID techniques are plagued to security and privacy issues due to underlying wireless communication channel. In order to come up with a solution, we propose an efficient authentication scheme which uses pseudorandom number generators (PRNG) and some simple cryptographic operations. Moreover, as the current generation tags come with in-built pseudo random generators, the implementations of these operations are possible with low complexity. The secret information stored inside the tags is communicated in a more secure way ensuring confidentiality, integrity, and authentication. The security of our proposed scheme is analyzed against different attacks on RFID and with the performance of some existing protocols. Experimental results show a significant improvement in security with average cost, when compared with the existing techniques

Security Analysis of Niu et al. Authentication and Ownership Management Protocol

Over the past decade, besides authentication, ownership management protocols have been suggested to transfer or delegate the ownership of RFID tagged items. Recently, Niu et al. have proposed an authentication and ownership management protocol based on 16-bit pseudo random number generators and exclusive-or operations which both can be easily implemented on low-cost RFID passive tags in EPC global Class-1 Generation-2 standard. They claim that their protocol offers location and data privacy and also resists against desynchronization attack. In this paper, we analyze the security of their proposed authentication and ownership management protocol and show that the protocol is vulnerable to secret disclosure and desynchronization attacks. The complexity of most of the attacks are only two runs of the protocol and the success probability of the attacks are almost 1

Greenpass: Flexible and Scalable Authorization for Wireless Networks

Wireless networks break the implicit assumptions that supported authorization in wired networks (that is: if one could connect, then one must be authorized). However, ensuring that only authorized users can access a campus-wide wireless network creates many challenges: we must permit authorized guests to access the same network resources that internal users do; we must accommodate the de-centralized way that authority flows in real universities; we also must work within standards, and accommodate the laptops and systems that users already have, without requiring additional software or plug-ins. This paper describes our ongoing project to address this problem, using SPKI/SDSI delegation on top of X.509 keypair within EAP-TLS. Within the ``living laboratory\u27\u27 of Dartmouth\u27s wireless network, this project lets us solve real problem with wireless networking, while also experimenting with trust flows and testing the limits of current tools

Greenpass RADIUS Tools for Delegated Authorization in Wireless Networks

Dartmouth\u27s Greenpass project extends how public key cryptography can be used to secure the wireless LAN with a RADIUS (Remote Authentication Dial In User Service) server that is responsible for handling authentication requests from clients (called supplicants in the 802.1x authentication model). This thesis describes the design and implementation of the authentication process of Greenpass, specifically what decisions are made in determining who is granted access and how a small modification of already existing protocols can be used to provide guest access in a way that better reflects how delegation of authority works in the real world. Greenpass takes advantage of the existing PKI to authenticate local Dartmouth users via X.509 identity certificates using EAP-TLS. We use the flexibility of SPKI/SDSI (Simple Public Key Infrastructure/Simple Distributed Security Infrastructure) authorization certificates to distribute the responsibility of delegating access to guests to certain authorized delegators, avoiding some of the necessary steps and paperwork associated with having a large centralized entity responsible for the entire institution. This thesis also discusses how our solution can be adapted to support different methods of guest delegation and investigates the possibility of eliminating the cumbersome central entity and administrative overhead traditionally associated with public key cryptography