Tight lower bounds for linear 2-query LCCs over finite fields
Combinatorica, 2016•Springer
Abstract A Locally Correctable Code (LCC) is an error correcting code that has a
probabilistic self-correcting algorithm that, with high probability, can correct any coordinate
of the codeword by looking at only a few other coordinates, even if a δ fraction of the
coordinates is corrupted. LCCs are a stronger form of LDCs (Locally Decodable Codes)
which have received a lot of attention recently due to their many applications and surprising
constructions. In this work, we show a separation between linear 2-query LDCs and LCCs …
probabilistic self-correcting algorithm that, with high probability, can correct any coordinate
of the codeword by looking at only a few other coordinates, even if a δ fraction of the
coordinates is corrupted. LCCs are a stronger form of LDCs (Locally Decodable Codes)
which have received a lot of attention recently due to their many applications and surprising
constructions. In this work, we show a separation between linear 2-query LDCs and LCCs …
Abstract
A Locally Correctable Code (LCC) is an error correcting code that has a probabilistic self-correcting algorithm that, with high probability, can correct any coordinate of the codeword by looking at only a few other coordinates, even if a δ fraction of the coordinates is corrupted. LCCs are a stronger form of LDCs (Locally Decodable Codes) which have received a lot of attention recently due to their many applications and surprising constructions.
In this work, we show a separation between linear 2-query LDCs and LCCs over finite fields of prime order. Specifically, we prove a lower bound of the form p Ω(δd) on the length of linear 2-query LCCs over F p , that encode messages of length d. Our bound improves over the known bound of 2 Ω(δd) [8,10,6] which is tight for LDCs. Our proof makes use of tools from additive combinatorics which have played an important role in several recent results in theoretical computer science.
We also obtain, as corollaries of our main theorem, new results in incidence geometry over finite fields. The first is an improvement to the Sylvester-Gallai theorem over finite fields [14] and the second is a new analog of Beck's theorem over finite fields.
The paper also contains an appendix, written by Sergey Yekhanin, showing that there do exist nonlinear LCCs of size 2 O(d) over F p , thus highlighting the importance of the linearity assumption for our result.
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