English

Exponential Lower Bound for 2-Query Locally Decodable Codes via a Quantum Argument

Quantum Physics 2007-05-23 v2 Computational Complexity

Abstract

A locally decodable code encodes n-bit strings x in m-bit codewords C(x), in such a way that one can recover any bit x_i from a corrupted codeword by querying only a few bits of that word. We use a quantum argument to prove that LDCs with 2 classical queries need exponential length: m=2^{Omega(n)}. Previously this was known only for linear codes (Goldreich et al. 02). Our proof shows that a 2-query LDC can be decoded with only 1 quantum query, and then proves an exponential lower bound for such 1-query locally quantum-decodable codes. We also show that q quantum queries allow more succinct LDCs than the best known LDCs with q classical queries. Finally, we give new classical lower bounds and quantum upper bounds for the setting of private information retrieval. In particular, we exhibit a quantum 2-server PIR scheme with O(n^{3/10}) qubits of communication, improving upon the O(n^{1/3}) bits of communication of the best known classical 2-server PIR.

Keywords

Cite

@article{arxiv.quant-ph/0208062,
  title  = {Exponential Lower Bound for 2-Query Locally Decodable Codes via a Quantum Argument},
  author = {Iordanis Kerenidis and Ronald de Wolf},
  journal= {arXiv preprint arXiv:quant-ph/0208062},
  year   = {2007}
}

Comments

16 pages Latex. 2nd version: title changed, large parts rewritten, some results added or improved