Kernkonzepte
Reducing control complexity in large-scale quantum computing through depth-optimal rectangular addressing.
Zusammenfassung
The content discusses the optimization of addressing a 2D qubit array with 1D controls using exact binary matrix factorization. It explores the balance between control granularity and flexibility for 2D qubit arrays, formulating the problem as an NP-hard one. The paper introduces a heuristic solver, row packing, that performs close to optimal solutions. It evaluates the methods on various benchmarks and discusses the implications for fault-tolerant quantum computing. The structure includes an introduction, background information, algorithm details, benchmark construction, evaluation results, and future directions.
Abstract:
- Reduction of control complexity crucial for large-scale quantum computing.
- Rectangular addressing balances granularity and flexibility for 2D qubit arrays.
- Depth-optimal rectangular addressing formulated as exact binary matrix factorization.
- Introduction of heuristic solver row packing for high-quality solutions.
Introduction:
- Motivation from successful experiments on neutral atom arrays platform.
- Acousto-optic deflector used to address qubits at row-column intersections.
- Quadratic reduction in bits required while maintaining individual addressability.
Algorithm:
- Formulation of depth-optimal rectangular addressing as exact binary matrix factorization.
- Introduction of SMT-based solver and heuristic row packing.
- SAP algorithm combines SMT solving and row packing for solutions.
Evaluation:
- Benchmark construction with random matrices and known optimal solutions.
- Row packing heuristic proves effective in finding optimal solutions.
- Performance comparison between trivial heuristic and row packing.
Fault-Tolerant Quantum Computing:
- Discussion on logical qubit operations using physical gates pattern.
- Tensor product approach for independent computation of rectangular partitions.
Conclusion:
- Consideration of future directions like introducing vacancies in atom arrays and investigating behavior under tensor product.
Statistiken
Reduction of control knobs may compromise individual qubit addressability while reducing complexity.
Quadratic reduction in bits required while preserving individual addressability.
SAP algorithm combines SMT solving and row packing for high-quality heuristics.
Zitate
"Rectangular partition is equivalent to biclique partition in graph theory."
"Row packing proves effective heuristic even on edge cases."