As superconducting processors scale, understanding how physical layout shapes qubit interactions is essential for architectural reliability. Existing methods offer limited insight into how electromagnetic design choices translate into execution-level behavior. We present EPAR, an electromagnetic-to-architecture framework that predicts robustness early directly from physical design by reconstructing how design distortion modifies the effective Hamiltonian, reroutes mediated connectivity, and influences control-pulse response. Across all tested layouts, EPAR's structural scores show 100% agreement with two-qubit error trends yet reveal over 10X robustness differences among edges with identical calibrated error rates, going beyond conventional metrics to provide improved and actionable compiler guidance.
@article{arxiv.2603.25671,
title = {EPAR: Electromagnetic Pathways to Architectural Reliability in Quantum Processors},
author = {Navnil Choudhury and Yizhuo Tan and Jiaqi Yu and Jakub Szefer and Kanad Basu},
journal= {arXiv preprint arXiv:2603.25671},
year = {2026}
}