Co-Designing Error Mitigation and Error Detection for Logical Qubits

Abstract

Near-term quantum workloads demand error management, yet the two lightest-weight techniques, Quantum Error Detection (QED) and Probabilistic Error Cancellation (PEC), have complementary cost profiles whose joint architectural design space remains unexplored. QED encodes logical qubits and discards error-flagged runs, filtering noise with low qubit overhead but leaving residual errors; PEC can correct these in software, but at exponential cost in noise strength. If QED efficiently reduces per-gate noise, PEC's cost savings can outweigh QED's discard overhead; realizing this, however, requires solving two system-level design challenges. First, the QED interval -- how often detection cycles are inserted -- is a tunable architectural parameter governing the cost-accuracy tradeoff. We derive an efficiency condition and show that the canonical one-cycle-per-gate frequency does not achieve break-even in any code we evaluate, while optimized intervals on high-rate Iceberg codes do. Second, we discover that naive PEC+QED integration degrades accuracy below the QED-only baseline. The root cause is a transient error profile in the first detection cycle that corrupts PEC's noise model. We develop steady-state extraction, a co-designed characterization protocol that isolates steady-state error behavior, reducing estimation bias by up to 10.2×. On a [[6,4,2]] Iceberg code running QAOA (p=4--8) with a fixed shot budget, PEC+QED achieves 2--11× lower absolute error and up to 31× lower MSE versus PEC on physical qubits, with per-interval savings compounding over interval depth.