Title :
One-Shot Lossy Quantum Data Compression
Author :
Datta, Nipu ; Renes, Joseph M. ; Renner, Renato ; Wilde, Mark M.
Author_Institution :
Stat. Lab., Univ. of Cambridge, Cambridge, UK
Abstract :
We provide a framework for one-shot quantum rate distortion coding, in which the goal is to determine the minimum number of qubits required to compress quantum information as a function of the probability that the distortion incurred upon decompression exceeds some specified level. We obtain a one-shot characterization of the minimum qubit compression size for an entanglement-assisted quantum rate-distortion code in terms of the smooth max-information, a quantity previously employed in the one-shot quantum reverse Shannon theorem. Next, we show how this characterization converges to the known expression for the entanglement-assisted quantum rate distortion function for asymptotically many copies of a memoryless quantum information source. Finally, we give a tight, finite blocklength characterization for the entanglement-assisted minimum qubit compression size of a memoryless isotropic qubit source subject to an average symbolwise distortion constraint.
Keywords :
data compression; quantum communication; entanglement-assisted quantum rate-distortion code; finite blocklength characterization; memoryless quantum information source; minimum qubit compression; one-shot lossy quantum data compression; one-shot quantum reverse Shannon theorem; quantum information; smooth max-information; Data compression; Distortion measurement; Entropy; Quantum entanglement; Rate distortion theory; Rate-distortion; Entanglement assistance; hypothesis testing; lossy quantum data compression; max-information; min- and max-entropy; quantum rate distortion; relative entropy;
Journal_Title :
Information Theory, IEEE Transactions on
DOI :
10.1109/TIT.2013.2283723
