Abstract. We design the first efficient algorithms and prove new combinatorial bounds for list decoding tensor products of codes and interleaved codes. • We show that for every code, the ratio of its list decoding radius to its minimum distance stays unchanged under the tensor product operation (rather than squaring, as one might expect). This gives the first efficient list decoders and new combinatorial bounds for some natural codes including multivariate polynomials where the degree in each variable is bounded. • We show that for every code, its list decoding radius remains unchanged under m-wise interleaving for an integer m. This generalizes a recent result of Dinur et al. [6], who proved such a result for interleaved Hadamard codes (eq...
We continue the study of list recovery properties of high-rate tensor codes, initiated by Hemenway, ...
AbstractFor Reed–Solomon codes with block length n and dimension k, the Johnson theorem states that ...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer...
Abstract. We design the first efficient algorithms and prove new combinatorial bounds for list decod...
We continue the study of list recovery properties of high-rate tensor codes, initiated by Hemenway, ...
We show combinatorial limitations on efficient list decoding of Reed-Solomon codes beyond the Johnso...
We give a polynomial time construction of binary codes with the best currently known trade-off betwe...
The weight distribution and list-decoding size of Reed-Muller codes are studied in this work. Given ...
We prove that binary linear concatenated codes with an outer algebraic code (specifically, a folded ...
A fundamental challenge in coding theory is to efficiently decode the original transmitted message e...
In this work we study the list-decoding size of Reed-Muller codes. Given a received word and a dista...
International audienceIn this paper we design a decoding algorithm based on a lifting decoding schem...
Presented on October 1, 2018 at 11:00 a.m. in the Pettit Microelectronics Research Center, Room 102 ...
For Reed-Solomon codes with block length n and dimension k, the Johnson theorem states that for a Ha...
We present a construction of subspace codes along with an efficient algorithm for list decoding from...
We continue the study of list recovery properties of high-rate tensor codes, initiated by Hemenway, ...
AbstractFor Reed–Solomon codes with block length n and dimension k, the Johnson theorem states that ...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer...
Abstract. We design the first efficient algorithms and prove new combinatorial bounds for list decod...
We continue the study of list recovery properties of high-rate tensor codes, initiated by Hemenway, ...
We show combinatorial limitations on efficient list decoding of Reed-Solomon codes beyond the Johnso...
We give a polynomial time construction of binary codes with the best currently known trade-off betwe...
The weight distribution and list-decoding size of Reed-Muller codes are studied in this work. Given ...
We prove that binary linear concatenated codes with an outer algebraic code (specifically, a folded ...
A fundamental challenge in coding theory is to efficiently decode the original transmitted message e...
In this work we study the list-decoding size of Reed-Muller codes. Given a received word and a dista...
International audienceIn this paper we design a decoding algorithm based on a lifting decoding schem...
Presented on October 1, 2018 at 11:00 a.m. in the Pettit Microelectronics Research Center, Room 102 ...
For Reed-Solomon codes with block length n and dimension k, the Johnson theorem states that for a Ha...
We present a construction of subspace codes along with an efficient algorithm for list decoding from...
We continue the study of list recovery properties of high-rate tensor codes, initiated by Hemenway, ...
AbstractFor Reed–Solomon codes with block length n and dimension k, the Johnson theorem states that ...
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer...