Stochastic magic-state production in fault-tolerant quantum computing inflates execution time but reduces peak resource demand, allowing stochastic-aware factory allocation to cut space-time volume by up to 27% and factories by up to 30% versus deterministic optima.
A game of surface codes: Large-scale quantum computing with lattice surgery
3 Pith papers cite this work. Polarity classification is still indexing.
3
Pith papers citing it
citation-role summary
background 1
citation-polarity summary
fields
quant-ph 3years
2026 3verdicts
UNVERDICTED 3roles
background 1polarities
background 1representative citing papers
O3LS reduces space overhead by up to 46.7% and time overhead by up to 36% in lattice surgery while suppressing logical error rates by up to an order of magnitude compared with prior layout and scheduling approaches.
Large qLDPC blocks in distributed quantum computing enable Pauli-based computation to run up to 10x faster than surface codes for optimization algorithms by using spare nodes to bypass serialization bottlenecks.
citing papers explorer
-
Price and Payoff: Non-Determinism in Fault Tolerant Quantum Computation
Stochastic magic-state production in fault-tolerant quantum computing inflates execution time but reduces peak resource demand, allowing stochastic-aware factory allocation to cut space-time volume by up to 27% and factories by up to 30% versus deterministic optima.
-
O3LS: Optimizing Lattice Surgery via Automatic Layout Searching and Loose Scheduling
O3LS reduces space overhead by up to 46.7% and time overhead by up to 36% in lattice surgery while suppressing logical error rates by up to an order of magnitude compared with prior layout and scheduling approaches.
-
Space-Time Tradeoffs of Pauli-Based Computation in Distributed qLDPC Architectures
Large qLDPC blocks in distributed quantum computing enable Pauli-based computation to run up to 10x faster than surface codes for optimization algorithms by using spare nodes to bypass serialization bottlenecks.