Multiset-Partition Distribution Matching

TL;DR

This paper introduces multiset-partition distribution matching (MPDM), a novel method that improves rate loss and efficiency over traditional CCDM by allowing more output sequences with the same composition, demonstrated through simulations on 64-QAM.

Contribution

We propose MPDM, a new distribution matching technique that partitions multisets to reduce rate loss and improve efficiency compared to CCDM.

Findings

MPDM achieves 2.5 to 5 times block-length savings over CCDM.

MPDM reduces rate loss in probabilistic amplitude shaping.

Simulation results show improved performance at medium to high SNRs.

Abstract

Distribution matching is a fixed-length invertible mapping from a uniformly distributed bit sequence to shaped amplitudes and plays an important role in the probabilistic amplitude shaping framework. With conventional constantcomposition distribution matching (CCDM), all output sequences have identical composition. In this paper, we propose multisetpartition distribution matching (MPDM) where the composition is constant over all output sequences. When considering the desired distribution as a multiset, MPDM corresponds to partitioning this multiset into equal-size subsets. We show that MPDM allows to address more output sequences and thus has lower rate loss than CCDM in all nontrivial cases. By imposing some constraints on the partitioning, a constructive MPDM algorithm is proposed which comprises two parts. A variable-length prefix of the binary data word determines the composition to be used, and the remainder of the input word is mapped with a conventional CCDM algorithm, such as arithmetic coding, according to the chosen composition. Simulations of 64-ary quadrature amplitude modulation over the additive white Gaussian noise channel demonstrate that the block-length saving of MPDM over CCDM for a fixed gap to capacity is approximately a factor of 2.5 to 5 at medium to high signal-to-noise ratios (SNRs).