Archive for year: 2013

Quantum physics opens up a variety of possibilities for radical new applications such as quantum cryptography, a discipline to which Romain Alléaume, researcher at the Institut Mines-Télécom, devotes his energy. Member of the Quantum Information team at Télécom ParisTech, the researcher uses specifically quantum properties of light to design and create systems allowing confidential data to be remotely transmitted. His most recent work addresses the security of these quantum devices as well as their compatibility with ‘traditional’ telecommunications networks.

Curiosity and amazement are what attract many people to the world of quantum physics. Romain Alléaume likewise was intrigued by these counterintuitive laws of nature, among them the principle of quantum superposition: “a quantum system may be in several different states at the same time”; the observer effect: “what is equally surprising is that the act of measuring a quantum object to find out what state it is in, changes that state”; as well as quantum entanglement, another special quantum feature: “it refers to correlations between quantum particles that prevent them from being described separately”. Researchers have taken advantage of these confusing properties and in the 1980s started to come up with a new way of processing data. But it has not been plain sailing, as the researcher explains: “one fundamental difficulty of designing a quantum computer stems from the fact that quantum data units, called ‘qubits’ must be able to interact with each other and be modified very quickly while remaining incredibly well protected from the outside environment.” But as paradoxical as it may seem, the quantum computer is not just a fanciful idea, since it actually exists experimentally, the largest to date being 14 qubits.

The benefits of the multidisciplinary environment at the Institut Mines-Télécom

Quantum data addresses a number of disciplines including physics, computer science and information theory. It requires the most advanced physics technology, such as that of cold atoms, superconductors and optics, and has mobilized numerous cutting-edge research teams. It was at Télécom ParisTech that Romain Alléaume began his research career setting up the ‘Quantum Information” team that has now grown in size, with four permanent researchers and around 15 members. “The Institut Mines-Télécom has played a critical role in establishing the team, notably through financial support and surface area allocation.” He recognizes that there are significant benefits to be had from working at the Institut Mines-Télécom: “there’s the multidisciplinary aspect (coding, discrete mathematics, physics, optics), a rich environment and an opening onto the market.” Such an environment has been made even more fertile since Romain Alléaume decided to set up his company, encouraged and advised by the school.

In 2008 he launched his industrial venture and co-founded SeQureNet, a startup company designing quantum cryptography systems. Better known by its acronym QKD (Quantum Key Distribution), quantum cryptography, usually using a fiber optic link, allows confidential information to be transmitted with significantly improved security compared to that of standard cryptography. The data is encoded into light, in the polarization of the photons for example. SeQureNet uses a technology called ‘continuous variable quantum cryptography’, the fruit of work at the Institut d’optique Graduate School and at Thales, and which is today developed at the Institut Mines-Télécom. This technology offers several important advantages: a detector system that provides efficient protection from interference and good compatibility with current infrastructures. Based simply on standard telecoms components, it does not require the use of specialised fibers.

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SeQureNet, a company born in the laboratory

Founded in 2008, SeQureNet is an offshoot of the ‘quantum data’ team at the Institut Mines-Télécom which develops and markets innovative technology offering enhanced security for communication networks. Since 2012 SeQureNet has been marketing Cygnus, a QKD system that only uses standard components; with this system the company took part in the experimental demonstration that broke the world distance record for this technology: 80 km compared to 25 km previously. On 14th April 2013 this work was published online by the research journal Nature Photonics in an article entitled ‘Experimental demonstration of long-distance continuous-variable quantum key distribution’ by P. Jouguet, S. Kunz-Jacques, A. Leverrier, E. Diamanti and P. Grangier. Cygnus has already attracted the interest of the NICT (Japanese National Institute of Information and Communications Technology) in Japan, which has bought it. Two types of application are envisioned: academic and industrial R&D (deployment, networks and security) and the protection of infrastructures (defense and telecom operators), with the main advantage being QKD’s capacity to assure secure data exchanges over the long term. Learn more[/box]

Long-term security

The idea underpinning QKD is to use the observer effect to turn an apparent weakness into an asset. Anyone trying to ‘read’ the photon messenger would disturb its quantum state and introduce errors, thus making it impossible for a spy to get correspondents to share and use a key that they believe to to be secure but which has been intercepted. Another fundamental competitive edge is QKD’s long-term security, which standard cryptography cannot guarantee. For example, the security of RSA, the groundbreaking public-key cryptography algorithm invented by Rivest, Shamir and Adleman[1], relies upon a conjecture: the difficulty of factoring large numbers. But as Romain Alléaume suggests, “Nothing stops you recording everything today in the hope of cracking the code tomorrow!” With QKD, on the other hand, a key that is secure today will still be so in 20 years’ time. QKD’s intrinsic security has compelled the researcher to try and integrate it into networks. This is a challenge that he has been tackling since 2004 with the European project SECOQC, and which in 2008 led to the opening of the first European QKD network.

Today the team is working on improving QKD’s performance as well as on its integration into optical network infrastructures through collaboration between Télécom ParisTech and SeQureNet. But these are not the only objectives: the systems’ practical security is also an important issue, particularly for industrialization. “In the cryptography field you expect to be challenged, especially when you have to be compared to already existing systems which are subjected to very extensive certification tests.” It has been found that the physical systems of QKD may also contain flaws, and that they should therefore undergo preventative testing. Such a reversal has not escaped Romain Alléaume: “this calls into question exactly what QKD was so proud of: the universality and infallibility of its security. Part of my current work focuses on this point: looking at potential attacks and developing counter-measures in order to guarantee QKD’s security.” For this young discipline it is perhaps the price to be paid in the shift up to maturity. There is, however, a new approach based upon the notion of entanglement that guarantees quantum systems’ security to in spite of the imperfection of the hardware used. Entangled photon sources open up considerable research prospects not only in cryptography, but also for manufacturing ‘quantum repeaters’: an opportunity for the researcher and his team to conduct exciting new research!

[1] RSA encryption (named after the initials of its three inventors Rivest, Shamir and Adleman) is an asymmetric cryptography algorithm calculated in 1977 and is frequently used in electronic commerce as well as, more generally, to exchange confidential data over the internet.

In today’s society, IT security systems are seriously put to the test: cloud data storage, the omnipresence of micro chips, social networking… Not only does constant communication via networks expose cryptographic systems to multitudes of threatening connections, but security mechanisms must also now function on devices with weak computing capacity, such as mobile phones. The older algorithms are under strain, and increasingly vulnerable to identity fraud and other violations of privacy. Institut Mines-Télécom, and specifically, the Télécom SudParis R3S (Réseaux, systèmes, services et sécurité – Networks, systems, services and security) team led by Maryline Laurent, is facing up the challenge of making these systems secure. The work of this team, conducted in collaboration with other research laboratories and industrial partners, focuses on developing new architecture and advanced cryptographic technology.

One of the most significant contemporary security problems is data storage in clouds: “Nowadays, a system fitted with a single entry point is relatively easy to secure,” explains Maryline Laurent, “but when a cloud is distributed on any hardware featuring (disc) storage resources, the protection of confidential data against potential criminals becomes a real problem.” This is an issue for private users just as much as it is for professionals, given that routers (Internet provider boxes) connect our domestic devices to a worldwide system.

The R3S team is working in partnership with telephone service providers such as Orange to come up with solutions capable of improving the security of content. Their goal: to ensure that content remains confidential and anonymous. Maryline Laurent explains: “Each user on a network is provided with a unique identifier in order to be recognised. We adopted a two-stage approach, the first stage enabling the encryption of data using a symmetric key and the second stage enabling the symmetric key to be secured within the cloud using the ID-based method; the symmetric key, which enables encryption and decryption, is generated by the users based on their identifier.” Consequently, not only would hackers be unable to read the data if stolen, but they would not even be able to tell who the data belongs to.

Furthermore, the standard ID-based method now appears to be insufficient for open systems such as cloud computing. More often than not it is not just a single user, but entire groups of users who share and access the same data. A further refinement has therefore been implemented: “To increase security, we decided that our ID-based encryption would generate its key not just from the unique user identifier, but also from the data itself.” This provides a unique cloud, where each piece of data has its own unique identifier providing a summary of its content. To find data in such a system, you need to know what you are looking for.

The challenge of securing a passive system

However this method requires a high level of processing power on the part of the user, while today’s systems are increasingly portable and scaled down. “A further challenge,” says Maryline Laurent “is being able to quickly authenticate devices such as smart phones, which are limited to carrying out simple processing operations.” Whether by use of a password or some other means, this authentication should provide evidence that the network user is who they say they are.

Maryline Laurent has carried out research on an extreme case of lack of power, in relation to RFID (Radio Frequency Identification) chips, which are tiny and yet play an important role in identifying remote devices. The security drawbacks of RFID chips explain why Europe is so reluctant to use them. A new European regulation should also enable general regulations on data protection to be updated. In the United States, industrial groups have already established uses for RFID chips, which are, for example, now replacing labels and barcodes at Walmart. Incorporated within daily objects, they could even allow a handbag to be scanned instantly to see if it contains the cigarette lighter you’re looking for, or a stolen ring. However, this quickly poses a threat to privacy: without strong authentification, anyone could potentially search your bag without permission! Success in blocking access could be the key to opening the European market to RFID chips.

Resolving the issue of lack of power required an innovative solution. “We took the NTRU (N-th degree truncated polynomial ring) method, a highly promising public key method, and adapted it. It is now possible to divide up the cryptographic processes: the entire workload is given to the server and the RFID chip only has a few binary operations to perform.”

Technically, what has been developed is a light system of two-way authentification where the processing principle consists of converting the NTRU into a binary polynomial and proposing a new method of generating/multiplying polynomials. “We can now carry out multiplication using simple shift operations.”

RFID chips will also benefit from strong authentification. “Our RFID chips project is highly advanced and has enabled us to register two patents. And if this encryption functions on passive chips, it will of course function on any machine.”

Taking back control of identity

These two developments allow data to be secured, but there is another element to take into account in order for users to put their trust into the systems: the security of data flows. Maryline Laurent explains: “The classic example is Facebook; if you return to Facebook a year after you have unsubscribed, you will find that all the data in your profile has been retained. This does not comply with the right to erasure of data outlined by European regulations. In social networks as they are today, users are losing control of the information they transmit and produce, and are unaware of the location of their data, of whether it has been duplicated and who has access to it.”

Maryline Laurent’s team are working on this issue alongside the W3C (World Wide Web Consortium), the organisation which works to standardize web technologies. The concept works by testing solutions which enable the user to manage access and distribution of their data on a social network, using a resource named MyProfile. Amongst other things, the user is able to physically control their data, as if it appeared on a home computer. It is not the data of the user which is transmitted, but solely its location on the hard disk. This is made possible using semantic web technology, meaning the network is required to connect to the disk in order to access the data. Using this approach, if users wish to erase their data there is no way for anyone to gain access to it.

Unfortunately, it will be difficult to get social networks to adopt these privacy-respecting technologies, which are clearly a disadvantage to them. The solution is therefore to establish new rival networks. The general public is becoming increasingly aware of the risks and will, in theory, eventually migrate towards networks which will respect their privacy, giving them greater control over their personal data.

Maintaining security

Despite all these measures, is it possible for data to ever be truly secure? We are increasingly entrusting our secrets to a growing number of people. Ultimately, vulnerability does not occur as a result of the system but of the user: “Users do not really understand the consequences of decisions they make in relation to data and system security,” explains Maryline Laurent. “Our role as researchers is to come up with solutions to protect users from the risks connected with new technologies, to guide their decision making, and to give them the confidence to know that their efforts are not in vain.”