Optimized Compilation of Logical Clifford Circuits
Abstract
Fault-tolerant quantum computing hinges on efficient logical compilation, in particular, translating high-level circuits into code-compatible implementations. Gate-by-gate compilation often yields deep circuits, requiring significant overhead to ensure fault-tolerance. As an alternative, we investigate the compilation of primitives from quantum simulation as single blocks. We focus our study on the [[n,n-2,2]] code family, which allows for the exhaustive comparison of potential compilation primitives on small circuit instances. Based upon that, we then introduce a methodology that lifts these primitives into size-invariant, depth-efficient compilation strategies. This recovers known methods for circuits with moderate Hadamard counts and yields improved realizations for sparse and dense placements. Simulations show significant error-rate reductions in the compiled circuits. We envision the approach as a core component of peephole-based compilers. Its flexibility and low hand-crafting burden make it readily extensible to other circuit structures and code families.
Cite
@article{arxiv.2602.12831,
title = {Optimized Compilation of Logical Clifford Circuits},
author = {Alexander Popov and Nico Meyer and Daniel D. Scherer and Guido Dietl},
journal= {arXiv preprint arXiv:2602.12831},
year = {2026}
}
Comments
This work has been submitted to the IEEE for possible publication. 8 pages, 7 figures