Title :
Exact solution for the max-min quantum error recovery problem
Author_Institution :
Dept. of Appl. Phys. & Physico-Inf., Keio Univ., Yokohama, Japan
Abstract :
This paper considers the max-min quantum error recovery problem; the recovery channel to be designed maximizes the fidelity between input and output states of a given noisy channel, while the minimum is taken over all possible pure input states. In general, this kind of max-min problem is cast as a non-convex optimization problem and is thus very hard to solve even with the aid of high-quality computational tools. Nevertheless, it is shown that, when the input takes a qubit, the problem is exactly convex for any size of error process. The Sum of Squares (SOS) characterization of a specific class of polynomial functions plays a crucial role in deriving this result.
Keywords :
concave programming; error correction; minimax techniques; quantum communication; error process; exact solution; max-min quantum error recovery problem; noisy channel; non-convex optimization problem; polynomial functions; recovery channel; sum of squares characterization; Chromium; Decoding; Error correction; Error correction codes; Linear matrix inequalities; Noise reduction; Polynomials; Protocols; Quantum mechanics; Redundancy;
Conference_Titel :
Decision and Control, 2009 held jointly with the 2009 28th Chinese Control Conference. CDC/CCC 2009. Proceedings of the 48th IEEE Conference on
Conference_Location :
Shanghai
Print_ISBN :
978-1-4244-3871-6
Electronic_ISBN :
0191-2216
DOI :
10.1109/CDC.2009.5400142
