*15:17* [Pub][ePrint]
A Generalised Formula for Calculating the Resilience of Random Key Predistribution Schemes, by Ed Kendall and Michelle Kendall and Wilfrid S. Kendall
A commonly used metric for comparing the resilience of key predistribution schemes is $\\fail_s$, which measures the proportion of network connections which are `broken\' by an adversary which has compromised $s$ nodes. In `Random key predistribution schemes for sensor networks\', Chan, Perrig and Song present a formula for measuring the resilience in a class of random key predistribution schemes called $q$-composite schemes. We present a correction to this formula for schemes where more than one key may be used to secure a link between a pair of nodes. Our corrected formula features an additional parameter which makes it applicable to a wider variety of random key predistribution schemes, including the original Eschenauer Gligor scheme. We also present a simplification of the formula for calculating connectivity.We refer to the recent paper by Yum and Lee which also claims to correct the original formula for the $q$-composite scheme. However the resulting formula is complicated, computationally demanding, and hard to understand. The formula which we propose and prove is easily computable and can be applied to a wider range of schemes.

*15:17* [Pub][ePrint]
Simple construction of epsilon-biased distribution, by Long Hoang Nguyen and Andrew William Roscoe
Epsilon-biased distribution has many applications in practice, including universal hashing computation. In this paper we will improve an existing epsilon-biased distribution construction due to Alon et al. that requires to uniformly and efficiently sample irreducible polynomials of a large degree, e.g. between 80 and 160. To remove the need for such a sampling which can be computationally expensive, we will replace the irreducible polynomials by random monic polynomials of higher degree, i.e. every degree r monic polynomial whether irreducible or reducible is selected with the same probability 2^{-r}. To analyse the security of the scheme, we need to find the maximum number of degree r polynomials that divide a degree n polynomial where n > r.

*15:17* [Pub][ePrint]
A formal study of two physical countermeasures against side channel attacks, by Sébastien Briais and Sylvain Guilley and Jean-Luc Danger
Secure electronic circuits must implement countermeasures against a wide range of attacks.Often, the protection against side channel attacks requires to be tightly integrated within the functionality to be protected.

It is now part of the designer\'s job to implement them.

But this task is known to be error-prone, and with current development processes, countermeasures are evaluated often very late (at circuit fabrication).

In order to improve the confidence of the designer in the efficiency of the countermeasure,

we suggest in this article to resort to formal methods early in the design flow for two reasons.

First of all, we intend to check that the process of transformation of the design from the vulnerable description to the protected one does not alter the functionality.

Second, we wish to prove that the security properties (that can derive from a formal security functional specification) are indeed met after transformation.

Our first contribution is to show how such a framework can be setup (in COQ) for netlist-level protections.

The second contribution is to illustrate that this framework indeed allows to detect vulnerabilities in dual-rail logics.

*15:17* [Pub][ePrint]
On the Security of Dynamic Group Signatures: Preventing Signature Hijacking, by Yusuke Sakai and Jacob C.N. Schuldt and Keita Emura and Goichiro Hanaoka and Kazuo Ohta
We identify a potential weakness in the standard security model for dynamic group signatures which appears to have been overlooked previously. More specifically, we highlight that even if a scheme provably meets the security requirements of the model, a malicious group member can potentially claim ownership of a group signature produced by an honest group member by forging a proof of ownership. This property leads to a number of vulnerabilities in scenarios in which dynamic group signatures are likely to be used. We furthermore show that the dynamic group signature scheme by Groth (ASIACRYPT 2007) does not provide protection against this type of malicious behavior.To address this, we introduce the notion of \\emph{opening soundness} for group signatures which essentially requires that it is infeasible to produce a proof of ownership of a valid group signature for any user except the original signer. We then show a relatively simple modification of the scheme by Groth which allows us to prove opening soundness for the modified scheme without introducing any additional assumptions.

We believe that opening soundness is an important and natural security requirement for group signatures, and hope that future schemes will adopt this type of security.

*15:17* [Pub][ePrint]
TorScan: Tracing Long-lived Connections and Differential Scanning Attacks, by Alex Biryukov, Ivan Pustogarov, Ralf-Philipp Weinmann
Tor is a widely used anonymity network providing low-latency communication capabilities. Around 400,000 users per day use Tor to route TCP traffic through a sequence of relays; three hops are selected from a pool of currently almost 3000 volunteer-operated Tor relays to comprise a route through the network for a limited time. In comparison to single-hop proxies, forwarding TCP streams through multiple relays increases the anonymity of the users significantly: each hop along the route only knows its successor and predecessor.The anonymity provided by Tor heavily relies on the hardness of linking a user\'s entry and exit nodes. If an attacker gains access to the topological information about the Tor network instead of having to consider the network as a fully connected graph, this anonymity may be reduced. In fact, we have found ways to probe the connectivity of a Tor relay. We demonstrate how the resulting leakage of the Tor network topology can be used and present attacks to trace back a user from an exit relay to a small set of potential entry nodes.

*15:17* [Pub][ePrint]
Impossibility Results for Static Input Secure Computation, by Sanjam Garg and Abishek Kumarasubramanian and Rafail Ostrovsky and Ivan Visconti
Consider a setting of two mutually distrustful parties Alice and Bob who want to securely evaluate some function on pre-specified inputs. The well studied notion of two-party secure computation

allows them to do so in the standalone setting. Consider a deterministic function (e.g., 1-out-of-2 bit

OT) that Alice and Bob can not evaluate trivially and which allows only Bob to receive the output. We

show that Alice and Bob can not securely compute any such function in the concurrent setting even

when their inputs are pre-specified. Our impossibility result also extends to all deterministic functions in

which both Alice and Bob get the same output. Our results have implications in the bounded-concurrent

setting as well.

*15:17* [Pub][ePrint]
Improved Publicly Verifiable Delegation of Large Polynomials and Matrix Computations, by Dario Fiore and Rosario Gennaro
We present new protocols for {\\em publicly verifiable} secure outsourcing of polynomials and matrix multiplication, which can be instantiated over RSA moduli, and proven secure under the DDH/RSA/Factoring Assumptions over such groups. Since all previous solutions are based on the use of bilinear maps, we demonstrate that publicly verifiable computation can be achieved even under different and standard assumptions.

Perhaps more interestingly, our solution can handle polynomials over finite fields of {\\em any} characteristic (starting from 2), and thus it can also support public verification of boolean formulas. This allows for a lot of flexibility, and it avoids the efficiency penalty of working bit by bit in fields larger than 2.

The core of our result is a new concept of Algebraic One-Way Functions which may be of independent interest.

*15:17* [Pub][ePrint]
A Publicly-Veriable Mix-net with Everlasting Privacy Towards Observers, by Denise Demirel and Jeroen van de Graaf
In this paper we present a novel, publicly verifiable mixingscheme which has everlasting privacy towards observers: all the information published on the bulletin board by the mixes (audit information etc) reveals no information about the identity of any of the messages published. The correctness of the mixing process is statistical: even if all authorities conspire, they cannot change the contents of any message without being detected with overwhelming probability. We accomplish this by encoding the messages submitted using so-called Pedersen commitments. Decoding (opening) these is possible because we create a parallel mix-net run by the same mixes to which the public has no access. This private mix-net uses the same permutations as the public one, but uses homomorphic encryption, which is used to send auxiliary information (messages, decommitment values) through the mix-net to allow decoding.