Title :
Reversible arithmetic coding for quantum data compression
Author :
Chuang, Isaac L. ; Modha, Dharmendra S.
Author_Institution :
IBM Almaden Res. Center, San Jose, CA, USA
fDate :
5/1/2000 12:00:00 AM
Abstract :
We study the problem of compressing a block of symbols (a block quantum state) emitted by a memoryless quantum Bernoulli source. We present a simple-to-implement quantum algorithm for projecting, with high probability, the block quantum state onto the typical subspace spanned by the lending eigenstates of its density matrix. We propose a fixed-rate quantum Shannon-Fano code to compress the projected block quantum state using a per-symbol code rate that is slightly higher than the von Neumann (1955) entropy limit. Finally, we propose quantum arithmetic codes to efficiently implement quantum Shannon-Fano (1948) codes. Our arithmetic encoder and decoder have a cubic circuit and a cubic computational complexity in the block size. Both the encoder and decoder are quantum-mechanical inverses of each other, and constitute an elegant example of reversible quantum computation
Keywords :
arithmetic codes; computational complexity; data compression; decoding; entropy; memoryless systems; probability; quantum computing; arithmetic decoder; arithmetic encoder; block quantum state; block size; cubic circuit; cubic computational complexity; density matrix; fixed-rate quantum Shannon-Fano code; lending eigenstates; memoryless quantum Bernoulli source; per-symbol code rate; probability; projected block quantum state; quantum algorithm; quantum arithmetic codes; quantum data compression; quantum-mechanical inverse; reversible arithmetic coding; reversible quantum computation; subspace; von Neumann entropy limit; Arithmetic; Block codes; DH-HEMTs; Data compression; Decoding; Entropy; Information theory; Physics; Quantum computing; Quantum mechanics;
Journal_Title :
Information Theory, IEEE Transactions on
