LLL reduction, originally founded in 1982 to factor certain polynomials, is a useful tool in public key cryptanalysis. The search for short lattice vectors helps determining the practical hardness of lattice problems, which are supposed to be secure against quantum computer attacks. It is a fact that in practice, the LLL algorithm finds much shorter vectors than its theoretic analysis guarantees. Therefore one can see that the guaranteed worst case bounds are not helpful for practical purposes. We use a probabilistic approach to give an estimate for the length of the shortest vector in an LLL-reduced bases that is tighter than the worst case bounds
The shortest vector problem (SVP) in lattices is related to problems in combinatorial optimization, ...
The LLL basis reduction algorithm was the first polynomial-time algorithm to compute a reduced basis...
Lattice reduction algorithms are notoriously hard to predict, both in terms of running time and outp...
LLL reduction, originally founded in 1982 to factor certain polynomials, is a useful tool in public ...
Abstract. Lattice reduction algorithms behave much better in practice than their theoretical analysi...
The Lenstra-Lenstra-Lovász basis reduction algorithm, also known as LLL algorithm, is an algorithm t...
AbstractTwo new lattice reduction algorithms are presented and analyzed. These algorithms, called th...
Abstract. Building upon a famous result due to Ajtai, we propose a sequence of lattice bases with gr...
We present a practical algorithm that given an LLL-reduced lattice basis of dimension n, runs in tim...
Lattice reduction algorithms are notoriously hard to predict, both in terms of running time and outp...
This paper is a tutorial introduction to the present state-of-the-art in the field of security of la...
We revisit the problem of generating a ``hard\u27\u27 random lattice together with a basis of relati...
In this article, we propose an adaptation of the algorithmic reduction theory of lattices to binary ...
We construct public-key cryptosystems that are secure assuming the *worst-case* hardness of approxim...
AbstractWe modify the concept of LLL-reduction of lattice bases in the sense of Lenstra, Lenstra, Lo...
The shortest vector problem (SVP) in lattices is related to problems in combinatorial optimization, ...
The LLL basis reduction algorithm was the first polynomial-time algorithm to compute a reduced basis...
Lattice reduction algorithms are notoriously hard to predict, both in terms of running time and outp...
LLL reduction, originally founded in 1982 to factor certain polynomials, is a useful tool in public ...
Abstract. Lattice reduction algorithms behave much better in practice than their theoretical analysi...
The Lenstra-Lenstra-Lovász basis reduction algorithm, also known as LLL algorithm, is an algorithm t...
AbstractTwo new lattice reduction algorithms are presented and analyzed. These algorithms, called th...
Abstract. Building upon a famous result due to Ajtai, we propose a sequence of lattice bases with gr...
We present a practical algorithm that given an LLL-reduced lattice basis of dimension n, runs in tim...
Lattice reduction algorithms are notoriously hard to predict, both in terms of running time and outp...
This paper is a tutorial introduction to the present state-of-the-art in the field of security of la...
We revisit the problem of generating a ``hard\u27\u27 random lattice together with a basis of relati...
In this article, we propose an adaptation of the algorithmic reduction theory of lattices to binary ...
We construct public-key cryptosystems that are secure assuming the *worst-case* hardness of approxim...
AbstractWe modify the concept of LLL-reduction of lattice bases in the sense of Lenstra, Lenstra, Lo...
The shortest vector problem (SVP) in lattices is related to problems in combinatorial optimization, ...
The LLL basis reduction algorithm was the first polynomial-time algorithm to compute a reduced basis...
Lattice reduction algorithms are notoriously hard to predict, both in terms of running time and outp...