On the Quantum Circuit Complexity Equivalence
摘要
Nielsen \cite{Nielsen05} recently asked the following question: "What is the minimal size quantum circuit required to exactly implement a specified -qubit unitary operation , without the use of ancilla qubits?" Nielsen was able to prove that a lower bound on the minimal size circuit is provided by the length of the geodesic between the identity and , where the length is defined by a suitable Finsler metric on . We prove that the minimum circuit size that simulates is in linear relation with the geodesic length and simulation parameters, for the given Finsler structure . As a corollary we prove the highest lower bound of O(\frac{% n^{4}}{p}d_{F_{p}}^{2}(I,U)L_{F_{p}}(I,\tilde{U})) and the lowest upper bound of , for the standard simulation technique. Therefore, our results show that by standard simulation one can not expect a better then times improvement in the upper bound over the result from Nielsen, Dowling, Gu and Doherty \cite{Nielsen06}. Moreover, our equivalence result can be applied to the arbitrary path on the manifold including the one that is generated adiabatically.
引用
@article{arxiv.quant-ph/0703082,
title = {On the Quantum Circuit Complexity Equivalence},
author = {Milosh Drezgich and Shankar Sastry},
journal= {arXiv preprint arXiv:quant-ph/0703082},
year = {2010}
}
备注
QIP 2007