English

Towards Quantum Belief Propagation for LDPC Decoding in Wireless Networks

Networking and Internet Architecture 2020-09-22 v2 Signal Processing Quantum Physics

Abstract

We present Quantum Belief Propagation (QBP), a Quantum Annealing (QA) based decoder design for Low Density Parity Check (LDPC) error control codes, which have found many useful applications in Wi-Fi, satellite communications, mobile cellular systems, and data storage systems. QBP reduces the LDPC decoding to a discrete optimization problem, then embeds that reduced design onto quantum annealing hardware. QBP's embedding design can support LDPC codes of block length up to 420 bits on real state-of-the-art QA hardware with 2,048 qubits. We evaluate performance on real quantum annealer hardware, performing sensitivity analyses on a variety of parameter settings. Our design achieves a bit error rate of 10810^{-8} in 20 μ\mus and a 1,500 byte frame error rate of 10610^{-6} in 50 μ\mus at SNR 9 dB over a Gaussian noise wireless channel. Further experiments measure performance over real-world wireless channels, requiring 30 μ\mus to achieve a 1,500 byte 99.99%\% frame delivery rate at SNR 15-20 dB. QBP achieves a performance improvement over an FPGA based soft belief propagation LDPC decoder, by reaching a bit error rate of 10810^{-8} and a frame error rate of 10610^{-6} at an SNR 2.5--3.5 dB lower. In terms of limitations, QBP currently cannot realize practical protocol-sized (e.g.,\textit{e.g.,} Wi-Fi, WiMax) LDPC codes on current QA processors. Our further studies in this work present future cost, throughput, and QA hardware trend considerations.

Keywords

Cite

@article{arxiv.2007.11069,
  title  = {Towards Quantum Belief Propagation for LDPC Decoding in Wireless Networks},
  author = {Srikar Kasi and Kyle Jamieson},
  journal= {arXiv preprint arXiv:2007.11069},
  year   = {2020}
}
R2 v1 2026-06-23T17:17:52.647Z