@article{3274,
abstract = {A boundary element model of a tunnel running through horizontally layered soil with anisotropic material properties is presented. Since there is no analytical fundamental solution for wave propagation inside a layered orthotropic medium in 3D, the fundamental displacements and stresses have to be calculated numerically. In our model this is done in the Fourier domain with respect to space and time. The assumption of a straight tunnel with infinite extension in the x direction makes it possible to decouple the system for every wave number kx, leading to a 2.5D-problem, which is suited for parallel computation. The special form of the fundamental solution, resulting from our Fourier ansatz, and the fact, that the calculation of the boundary integral equation is performed in the Fourier domain, enhances the stability and efficiency of the numerical calculations.},
author = {Rieckh, Georg and Kreuzer, Wolfgang and Waubke, Holger and Balazs, Peter},
journal = { Engineering Analysis with Boundary Elements},
number = {6},
pages = {960 -- 967},
publisher = {Elsevier},
title = {{A 2.5D-Fourier-BEM model for vibrations in a tunnel running through layered anisotropic soil}},
doi = {10.1016/j.enganabound.2011.12.014},
volume = {36},
year = {2012},
}
@inbook{3277,
abstract = {The problem of the origin of metazoa is becoming more urgent in the context of astrobiology. By now it is clear that clues to the understanding of this crucial transition in the evolution of life can arise in a fourth pathway besides the three possibilities in the quest for simplicity outlined by Bonner in his classical book. In other words, solar system exploration seems to be one way in the long-term to elucidate the simplicity of evolutionary development. We place these ideas in the context of different inheritance systems, namely the genotypic and phenotypic replicators with limited or unlimited heredity, and ask which of these can support multicellular development, and to which degree of complexity. However, the quest for evidence on the evolution of biotas from planets around other stars does not seem to be feasible with present technology with direct visualization of living organisms on exoplanets. But this may be attempted on the Galilean moons of Jupiter where there is a possibility of detecting reliable biomarkers in the next decade with the Europa Jupiter System Mission, in view of recent progress by landing micropenetrators on planetary, or satellite surfaces. Mars is a second possibility in the inner Solar System, in spite of the multiple difficulties faced by the fleet of past, present and future missions. We discuss a series of preliminary ideas for elucidating the origin of metazoan analogues with available instrumentation in potential payloads of feasible space missions to the Galilean moons.},
author = {de Vladar, Harold and Chela Flores, Julian},
booktitle = {Life on Earth and other planetary bodies},
pages = {387 -- 405},
publisher = {Springer},
title = {{Can the evolution of multicellularity be anticipated in the exploration of the solar system?}},
doi = {10.1007/978-94-007-4966-5_22},
volume = {24},
year = {2012},
}
@inproceedings{3279,
abstract = {We show a hardness-preserving construction of a PRF from any length doubling PRG which improves upon known constructions whenever we can put a non-trivial upper bound q on the number of queries to the PRF. Our construction requires only O(logq) invocations to the underlying PRG with each query. In comparison, the number of invocations by the best previous hardness-preserving construction (GGM using Levin's trick) is logarithmic in the hardness of the PRG. For example, starting from an exponentially secure PRG {0,1} n → {0,1} 2n, we get a PRF which is exponentially secure if queried at most q = exp(√n)times and where each invocation of the PRF requires Θ(√n) queries to the underlying PRG. This is much less than the Θ(n) required by known constructions.
},
author = {Jain, Abhishek and Pietrzak, Krzysztof Z and Tentes, Aris},
location = {Taormina, Sicily, Italy},
pages = {369 -- 382},
publisher = {Springer},
title = {{Hardness preserving constructions of pseudorandom functions}},
doi = {10.1007/978-3-642-28914-9_21},
volume = {7194},
year = {2012},
}
@inproceedings{3280,
abstract = {The (decisional) learning with errors problem (LWE) asks to distinguish "noisy" inner products of a secret vector with random vectors from uniform. The learning parities with noise problem (LPN) is the special case where the elements of the vectors are bits. In recent years, the LWE and LPN problems have found many applications in cryptography. In this paper we introduce a (seemingly) much stronger adaptive assumption, called "subspace LWE" (SLWE), where the adversary can learn the inner product of the secret and random vectors after they were projected into an adaptively and adversarially chosen subspace. We prove that, surprisingly, the SLWE problem mapping into subspaces of dimension d is almost as hard as LWE using secrets of length d (the other direction is trivial.) This result immediately implies that several existing cryptosystems whose security is based on the hardness of the LWE/LPN problems are provably secure in a much stronger sense than anticipated. As an illustrative example we show that the standard way of using LPN for symmetric CPA secure encryption is even secure against a very powerful class of related key attacks. },
author = {Pietrzak, Krzysztof Z},
location = {Taormina, Sicily, Italy},
pages = {548 -- 563},
publisher = {Springer},
title = {{Subspace LWE}},
doi = {10.1007/978-3-642-28914-9_31},
volume = {7194},
year = {2012},
}
@inproceedings{3281,
abstract = {We consider the problem of amplifying the "lossiness" of functions. We say that an oracle circuit C*: {0,1} m → {0,1}* amplifies relative lossiness from ℓ/n to L/m if for every function f:{0,1} n → {0,1} n it holds that 1 If f is injective then so is C f. 2 If f has image size of at most 2 n-ℓ, then C f has image size at most 2 m-L. The question is whether such C* exists for L/m ≫ ℓ/n. This problem arises naturally in the context of cryptographic "lossy functions," where the relative lossiness is the key parameter. We show that for every circuit C* that makes at most t queries to f, the relative lossiness of C f is at most L/m ≤ ℓ/n + O(log t)/n. In particular, no black-box method making a polynomial t = poly(n) number of queries can amplify relative lossiness by more than an O(logn)/n additive term. We show that this is tight by giving a simple construction (cascading with some randomization) that achieves such amplification.},
author = {Pietrzak, Krzysztof Z and Rosen, Alon and Segev, Gil},
location = {Taormina, Sicily, Italy},
pages = {458 -- 475},
publisher = {Springer},
title = {{Lossy functions do not amplify well}},
doi = {10.1007/978-3-642-28914-9_26},
volume = {7194},
year = {2012},
}