Compression of sources of probability distributions and density operators

We study the problem of efficient compression of a stochastic source of probability distributions. It can be viewed as a generalization of Shannon's source coding problem. It has relation to the theory of common randomness, as well as to channel coding and rate--distortion theory: in the first two subjects ``inverses'' to established coding theorems can be derived, yielding a new approach to proving converse theorems, in the third we find a new proof of Shannon's rate--distortion theorem. After reviewing the known lower bound for the optimal compression rate, we present a number of approaches to achieve it by code constructions. Our main results are: a better understanding of the known lower bounds on the compression rate by means of a strong version of this statement, a review of a construction achieving the lower bound by using common randomness which we complement by showing the optimal use of the latter within a class of protocols. Then we review another approach, not dependent on common randomness, to minimizing the compression rate, providing some insight into its combinatorial structure, and suggesting an algorithm to optimize it. The second part of the paper is concerned with the generalization of the problem to quantum information theory: the compression of mixed quantum states. Here, after reviewing the known lower bound we contribute a strong version of it, and discuss the relation of the problem to other issues in quantum information theory.

[1]  J. Wolfowitz Coding Theorems of Information Theory , 1962, Ergebnisse der Mathematik und Ihrer Grenzgebiete.

[2]  Rudolf Ahlswede,et al.  Common randomness in information theory and cryptography - I: Secret sharing , 1993, IEEE Trans. Inf. Theory.

[3]  Aaron D. Wyner,et al.  Coding Theorems for a Discrete Source With a Fidelity CriterionInstitute of Radio Engineers, International Convention Record, vol. 7, 1959. , 1993 .

[4]  Rudolf Ahlswede,et al.  Common Randomness in Information Theory and Cryptography - Part II: CR Capacity , 1998, IEEE Trans. Inf. Theory.

[5]  Prakash Narayan,et al.  Reliable Communication Under Channel Uncertainty , 1998, IEEE Trans. Inf. Theory.

[6]  M. Horodecki Limits for compression of quantum information carried by ensembles of mixed states , 1997, quant-ph/9712035.

[7]  Andreas J. Winter Coding theorems of quantum information theory , 1999 .

[8]  Ashish V. Thapliyal,et al.  Entanglement-Assisted Classical Capacity of Noisy Quantum Channels , 1999, Physical Review Letters.

[9]  Andreas J. Winter,et al.  Coding theorem and strong converse for quantum channels , 1999, IEEE Trans. Inf. Theory.

[10]  Emina Soljanin Compressing Mixed-State Sources by Sending Classical Information , 2001 .

[11]  What is Possible Without Disturbing Quantum Signals , 2001 .

[12]  J. Cirac,et al.  Visible compression of commuting mixed states , 2001, quant-ph/0101111.

[13]  A. Winter ‘‘Extrinsic’’ and ‘‘Intrinsic’’ Data in Quantum Measurements: Asymptotic Convex Decomposition of Positive Operator Valued Measures , 2001, quant-ph/0109050.

[14]  R. Jozsa,et al.  On quantum coding for ensembles of mixed states , 2000, quant-ph/0008024.

[15]  Serap A. Savari,et al.  Quantum Data Compression of Ensembles of Mixed States with Commuting Density Operators , 2001 .

[16]  Dave Bacon,et al.  Classical simulation of quantum entanglement without local hidden variables , 2001 .

[17]  A. Winter,et al.  Trading quantum for classical resources in quantum data compression , 2002, quant-ph/0204038.

[18]  S. Popescu,et al.  Classical analog of entanglement , 2001, quant-ph/0107082.

[19]  Peter W. Shor,et al.  Entanglement-assisted capacity of a quantum channel and the reverse Shannon theorem , 2001, IEEE Trans. Inf. Theory.

[20]  Rudolf Ahlswede,et al.  Strong converse for identification via quantum channels , 2000, IEEE Trans. Inf. Theory.