Work place: London Metropolitan University/Cyber Research Centre, London, N7 8DB, UK
E-mail: arp0264@my.londonmet.ac.uk
Website:
Research Interests:
Biography
Anthony Phipps is a member of the cyber research centre at London Metropolitan University, conducting research into audio based cyber security applications. His interests include steganography, the cyber security aspects of digital accessibility, and voice computing. He started his career as an engineer in electrical and electronic engineering. For over two decades he has specialised in Information and Physical Security in the energy and financial services sectors. He obtained his first degree in Electrical and Electronic Engineering from the University of Greenwich in 1997 and a masters degree from University of Westminster in Information Technology Security in 2002. He is currently a Lead Engineer for Lloyds Banking Group, managing a team of security design engineers and architects.
By Anthony Phipps Karim Ouazzane Vassil Vassilev
DOI: https://doi.org/10.5815/ijcnis.2022.03.01, Pub. Date: 8 Jun. 2022
Although authentication of users of digital voice-based systems has been addressed by much research and many commercially available products, there are very few that perform well in terms of both usability and security in the audio domain. In addition, the use of voice biometrics has been shown to have limitations and relatively poor performance when compared to other authentication methods. We propose using audio steganography as a method of placing authentication key material into sound, such that an authentication factor can be achieved within an audio channel to supplement other methods, thus providing a multi factor authentication opportunity that retains the usability associated with voice channels. In this research we outline the challenges and threats to audio and voice-based systems in the form of an original threat model focusing on audio and voice-based systems, we outline a novel architectural model that utilises audio steganography to mitigate the threats in various authentication scenarios and finally, we conduct experimentation into hiding authentication materials into an audible sound. The experimentation focused on creating and testing a new steganographic technique which is robust to noise, resilient to steganalysis and has sufficient capacity to hold cryptographic material such as a 2048 bit RSA key in a short audio music clip of just a few seconds achieving a signal to noise ratio of over 70 dB in some scenarios. The method developed was seen to be very robust using digital transmission which has applications beyond this research. With acoustic transmission, despite the progress demonstrated in this research some challenges remain to ensure the approach achieves its full potential in noisy real-world applications and therefore the future research direction required is outlined and discussed.
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