Posted
György P. Gehér, David Byfield, Archibald Ruban (Jul 28 2025).
Abstract: In this paper we construct a new family of quantum low-density parity-check (qLDPC) codes, which we call ``Directional Codes'', that outperforms the rotated planar code (RPC) while naturally meeting the connectivity requirements of the widely adopted square-grid, and some even the sparser hexagonal-grid. The key idea is to utilise the iSWAP gate -- a natural native gate for superconducting qubits -- to construct circuits that measure the stabilisers of these qLDPC codes without the need for any long-range connections or an increased degree of connectivity. We numerically evaluate the performance of directional codes, encoding four, six and twelve logical qubits, using a common superconducting-inspired circuit-level Pauli noise model. We also compare them to the RPC and to the bivariate bicycle (BB) codes, currently the two most popular quantum LDPC code families. As a concrete example, directional codes outperform RPC by achieving better QEC performance at physical error rate using only of the physical qubits at distance up to . Our discovery represents a breakthrough in QEC code design that suggests complex long-range, high-connectivity hardware may not be necessary for low-overhead fault-tolerant quantum computation.
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