Strictly Local Tile-Code Architectures on Two-Dimensional Planar Lattices
Abstract
Tile codes are a family of planar quantum low-density parity-check (qLDPC) codes with weight-6 stabilizers and open boundary conditions, offering an encoding efficiency of up to four times that of the surface code. In this work, we develop an exhaustive search algorithm for finding SWAP-based routing schemes that implement syndrome extraction for four tile-code families using only nearest-neighbor interactions on a two-dimensional square lattice, matching the connectivity of the surface code. Using explicitly constructed routed syndrome-extraction circuits decoded with BP+OSD, we estimate the circuit-level thresholds of these code families. For the SI1000 noise model, the threshold without such a connectivity constraint is obtained in a range 0.23%-0.31%, while it decreases to 0.11%-0.13% with routing, representing a reduction factor of around two to three. Despite this threshold penalty, our resource-footprint analysis shows that routed tile codes require fewer physical qubits per logical qubit than the surface code at sufficiently low physical error rates: Under the SI1000 noise model, we find a crossover near , below which routed tile codes become more qubit-efficient, with an advantage that grows monotonically as the physical error rate decreases.
Cite
@article{arxiv.2607.05897,
title = {Strictly Local Tile-Code Architectures on Two-Dimensional Planar Lattices},
author = {Yoonjin Bae and Chae-Yeun Park},
journal= {arXiv preprint arXiv:2607.05897},
year = {2026}
}
Comments
9+6 pages