Posted

Shuwen Kan, Zefan Du, Chenxu Liu, Meng Wang, Yufei Ding, Ang Li, Ying Mao, Samuel Stein (May 01 2025).
Abstract: Surface codes represent a leading approach for quantum error correction (QEC), offering a path towards universal fault-tolerant quantum computing (FTQC). However, efficiently implementing algorithms, particularly using Pauli-based computation (PBC) with lattice surgery, necessitates careful resource optimization. Prior work often employs static layouts and simplified error models. These typically fail to capture the full costs and dynamic nature of active computation, leading to resource bottlenecks and suboptimal architectural designs. To address this, we introduce SPARO. SPARO features a comprehensive logical error model based on a large corpus of numerical simulations encompassing active Pauli-based computation (PBC) operations-including Pauli product measurements (PPMs), idling qubits, and patch rotations. Our numerical models are integrated within an end-to-end compilation pipeline. SPARO analyzes algorithm-specific bottlenecks arising from constraints such as limited routing areas or magic-state factory throughput. SPARO then dynamically allocates available hardware resources, balancing compute, routing, and magic-state distillation, to minimize space-time overhead and logical error rates for specific workloads. Our simulations demonstrate that SPARO effectively identifies critical resource trade-offs. When evaluated on benchmark circuits, SPARO identifies resource configurations achieving up to 41.96% logical error rate reductions for 433-qubit ADDER circuits when compared to state-of-the-art static layouts using an identical total resource budget. This dynamic approach enables effective co-optimization of PBC execution and surface-code architectures, significantly improving overall resource efficiency. SPARO will be open sourced.

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