Quantum Oracle Interrogation: Getting all information for almost half the price
Abstract
Consider a quantum computer in combination with a binary oracle of domain size N. It is shown how N/2+sqrt(N) calls to the oracle are sufficient to guess the whole content of the oracle (being an N bit string) with probability greater than 95%. This contrasts the power of classical computers which would require N calls to achieve the same task. From this result it follows that any function with the N bits of the oracle as input can be calculated using N/2+sqrt(N) queries if we allow a small probability of error. It is also shown that this error probability can be made arbitrary small by using N/2+O(sqrt(N)) oracle queries. In the second part of the article `approximate interrogation' is considered. This is when only a certain fraction of the N oracle bits are requested. Also for this scenario does the quantum algorithm outperform the classical protocols. An example is given where a quantum procedure with N/10 queries returns a string of which 80% of the bits are correct. Any classical protocol would need 6N/10 queries to establish such a correctness ratio.
Cite
@article{arxiv.quant-ph/9805006,
title = {Quantum Oracle Interrogation: Getting all information for almost half the price},
author = {Wim van Dam},
journal= {arXiv preprint arXiv:quant-ph/9805006},
year = {2007}
}
Comments
11 pages LaTeX2e, 1 postscript figure; error analysis added; new section on approximate interrogation added