Two-dimensional Entanglement-assisted Quantum Quasi-cyclic Low-density Parity-check Codes

Abstract

For any positive integer g 2, we derive general condition for the existence of a 2g-cycle in the Tanner graph of two-dimensional (2-D) classical quasi-cyclic (QC) low-density parity-check (LDPC) codes. Depending on whether p is an odd prime or a composite number, we construct two distinct families of 2-D classical QC-LDPC codes with girth >4 by stacking p × p × p tensors. Furthermore, using generalized Behrend sequences, we propose an additional family of 2-D classical QC-LDPC codes with girth >6, constructed via a similar tensor-stacking approach. All the proposed 2-D classical QC-LDPC codes exhibit an erasure correction capability of at least p × p. Based on the constructed 2-D classical QC-LDPC codes, we derive two families of 2-D entanglement-assisted (EA) quantum low-density parity-check (QLDPC) codes. The first family of 2-D EA-QLDPC codes is obtained from a pair of 2-D classical QC-LDPC codes and is designed such that the unassisted part of the Tanner graph of the resulting EA-QLDPC code is free of 4-cycles, while requiring only a single ebit to be shared across the quantum transceiver. The second family is constructed from a single 2-D classical QC-LDPC code whose Tanner graph is free from 4-cycles. Moreover, the constructed EA-QLDPC codes inherit an erasure correction capability of p × p, as the underlying classical codes possess the same erasure correction property.