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Fat-Tree QRAM: A High-Bandwidth Shared Quantum Random Access Memory for Parallel Queries

Quantum Physics 2025-03-04 v2 Hardware Architecture

Abstract

Quantum Random Access Memory (QRAM) is a crucial architectural component for querying classical or quantum data in superposition, enabling algorithms with wide-ranging applications in quantum arithmetic, quantum chemistry, machine learning, and quantum cryptography. In this work, we introduce Fat-Tree QRAM, a novel query architecture capable of pipelining multiple quantum queries simultaneously while maintaining desirable scalings in query speed and fidelity. Specifically, Fat-Tree QRAM performs O(log(N))O(\log (N)) independent queries in O(log(N))O(\log (N)) time using O(N)O(N) qubits, offering immense parallelism benefits over traditional QRAM architectures. To demonstrate its experimental feasibility, we propose modular and on-chip implementations of Fat-Tree QRAM based on superconducting circuits and analyze their performance and fidelity under realistic parameters. Furthermore, a query scheduling protocol is presented to maximize hardware utilization and access the underlying data at an optimal rate. These results suggest that Fat-Tree QRAM is an attractive architecture in a shared memory system for practical quantum computing.

Keywords

Cite

@article{arxiv.2502.06767,
  title  = {Fat-Tree QRAM: A High-Bandwidth Shared Quantum Random Access Memory for Parallel Queries},
  author = {Shifan Xu and Alvin Lu and Yongshan Ding},
  journal= {arXiv preprint arXiv:2502.06767},
  year   = {2025}
}

Comments

17 pages, Accepted by ACM ASPLOS 2025. (V2)Fixing a formatting issue and adding new references

R2 v1 2026-06-28T21:39:01.783Z