Visible to the public Biblio

Filters: Keyword is source authentication  [Clear All Filters]
2020-04-06
Alamleh, Hosam, AlQahtani, Ali Abdullah S..  2020.  Two Methods for Authentication Using Variable Transmission Power Patterns. 2020 10th Annual Computing and Communication Workshop and Conference (CCWC). :0355–0358.
In the last decade, the adoption of wireless systems has increased. These systems allow multiple devices to send data wirelessly using radio waves. Moreover, in some applications, authentication is done wirelessly by exchanging authentication data over the air as in wireless locks and keyless entry systems. On the other hand, most of the wireless devices today can control the radio frequency transmission power to optimize the system's performance and minimize interference. In this paper, we explore the possibility of modulating the radio frequency transmission power in wireless systems for authentication purposes and using it for source authentication. Furthermore, we propose two system models that perform authentication using variable power transmission patterns. Then, we discuss possible applications. Finally, we implement and test a prototype system using IEEE 802.11 (Wi-Fi) devices.
2018-02-21
Win, E. K., Yoshihisa, T., Ishi, Y., Kawakami, T., Teranishi, Y., Shimojo, S..  2017.  A Lightweight Multi-receiver Encryption Scheme with Mutual Authentication. 2017 IEEE 41st Annual Computer Software and Applications Conference (COMPSAC). 2:491–497.

In this paper, we propose a lightweight multi-receiver encryption scheme for the device to device communications on Internet of Things (IoT) applications. In order for the individual user to control the disclosure range of his/her own data directly and to prevent sensitive personal data disclosure to the trusted third party, the proposed scheme uses device-generated public keys. For mutual authentication, third party generates Schnorr-like lightweight identity-based partial private keys for users. The proposed scheme provides source authentication, message integrity, replay-attack prevention and implicit user authentication. In addition to more security properties, computation expensive pairing operations are eliminated to achieve less time usage for both sender and receiver, which is favourable property for IoT applications. In this paper, we showed a proof of security of our scheme, computational cost comparison and experimental performance evaluations. We implemented our proposed scheme on real embedded Android devices and confirmed that it achieves less time cost for both encryption and decryption comparing with the existing most efficient certificate-based multi-receiver encryption scheme and certificateless multi-receiver encryption scheme.