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Please refer to the link below for a full description of the open positions.
More concretely, part of the research will involve the analysis and development of authentication protocols in specific settings. This will include investigating resistance of both existing and novel protocols against different types of attacks, theoretically and experimentally. In addition to investigating established settings, such as RFID authentication, the research will also explore more general authentication problems, such as those that arise in the context of trust in social networks, smartphone applications and collaborative data processing. This will be done by grounding the work in a generalised decision-making framework. The project should result in the development of theory and authentication mechanisms for noisy, constrained settings that strike an optimal balance between reliable authentication, privacy-preservation and resource consumption. Some previous research related to this research project can be found here: http://lasecwww.epfl.ch/~katerina/Publications.html
Applicants for the position shall have a Master’s Degree or corresponding in Computer Science, Informatics, Telecommunications, Information Security and Cryptography or in a related discipline. A master\\\'s degree in information security and cryptography is a bonus.
Experience in one or more of cryptography, probability and statistics, decision and game theory are ben
Traceable attribute-based signatures add anonymity revocation mechanisms to attribute-based signatures whereby a special tracing authority equipped with a secret key is capable of revealing the identity of the signer. Such a feature is important in settings where accountability and abuse prevention are required.
In this work, we first provide a formal security model for traceable attribute-based signatures. Our focus is on the more practical case where attribute management is distributed among different authorities rather than relying on a single central authority.
By specializing our model to the single attribute authority setting, we overcome some of the shortcomings of the existing model for the same setting.
Our second contribution is a generic construction for the primitive which achieves a strong notion of security. Namely, it achieves CCA anonymity and its security is w.r.t.\\ adaptive adversaries. Moreover, our framework permits expressive signing polices.
Finally, we provide some instantiations of the primitive whose security reduces to falsifiable intractability assumptions and without relying on idealized assumptions.
To advance the Development of Tools for the Design of Secure Embedded Systems, we are searching for the closest possible point in time a
Research Assistant (m/f)
for a full time position.
a position as research assistant which includes the ability to carry out a PhD thesis. With your research, you contribute to one of our main fields.
The position as research assistant is initially offered for a limited time of 2.5 years. It is paid according to TV-L E13.
TUM aims at increasing the percentage of women. Therefore, qualified women
For one of the positions we welcome applications from researchers working in algebra or geometry, especially in subareas that complement the expertise of our current faculty. Application areas of particular interest are cryptography, communication and computation.
A university-funded post-doc position is available in the RISCS center and the BU Security Group (BUsec), in the Department of Computer Science at Boston University. The successful candidates will have an established research track record in one or more of the following areas: systems security, network security, applied cryptography, or cybersecurity technology policy or law. The position is funded for one year, with an option to extend to two years based on performance and availability of funds. Tentative start date is September 2014, but earlier start dates are also possible.
The BU Security Group does research in cryptography and security within the Department of Computer Science. The BU Center for Reliable Information Systems & Cyber Security (RISCS) takes a multidisciplinary approach to security by bring together experts across several discipline. Both the group and the Center also benefit from collaboration with the vibrant cryptography, security, and tech policy community in the Boston area.
Most of our products are becoming connected to the cyber space. We are looking for top scientists with a strong mathematical background for strengthening our competences in digital cryptography and security and who can help us to build and offer competitive trusted solutions and services in Healthcare, Lifestyle and Lighting.
Your challenges and responsibilities will be:
- Inventing and validating in industrial project teams new digital security technologies for use in Philips products and services, making use of the Internet of Things and Cloud Computing;
- Creating innovation impact with your results in terms of intellectual property creation or research transfers into the business;
- Keeping our digital security competence at world-class level;
- Contributing to our research roadmap by new ideas and winning new proposals;
- Working together with external partners.
For more insights you can visit: http://www.research.philips.com/
We are looking for
The successful candidate has/is:
- A PhD in mathematics or computer science and a strong inclination to cryptography, preferably proven by relevant scientific results;
- Proven practical skills in computer simulation, system architecting and computer programming;
- Practical experiences in industry;
- A strong team playing attitude, expressed in taking the lead where appropriate, building on each other’s strengths and working in a cooperative way;
- A self-propelled enthusiast with a can-do mentality.Takes ownership for making it happen;
- Good communication skills and fluent in English.
Encryption , and evolved into Message Locked Encryption , strives to solve this problem. The latest work, DupLESS , proposes a server-aided architecture that provides the strongest privacy. The DupLESS architecture relies on a key server to help the clients generate encryption keys that result in convergent ciphertexts. In this paper, we first provide a rigorous proof of security, in the random oracle model, for the DupLESS architecture which is lacking in the original paper. Our proof shows that using additional secret, other than the data itself, for generating encryption keys achieves the best possible security under current deduplication paradigm.We then introduce a distributed protocol that eliminates the need for a key server and allows less managed systems such as P2P systems to enjoy the high security level. Implementation and evaluation show that the scheme is both robust and practical.