中文

Vectorizing Quantum Control: A RISC-V Vector Extension Architecture for Scalable Qubit Systems

硬件体系结构 2026-07-08 v1 量子物理

摘要

The Quantum Control Processor (QCP) bridges the gap between compiler toolchains and control electronics, and is responsible for translating compiled quantum circuits into executable instructions that directly manipulate qubits and handle measurement feedback. However, existing designs rely primarily on customized instruction sets, limiting design reuse and requiring significant effort to build supporting toolchains. Furthermore, efficiently addressing qubits and scheduling operations in highly scalable scenarios remains a critical challenge. In this work, we present a vectorized quantum control approach built upon the RISC-V Vector (RVV) engine with a quantum-oriented extension. Leveraging the high parallelism of RVV, our approach can address up to 128 qubits in a single instruction. We also embed parameterized rotation information into the instruction set, enabling dynamic tuning of gate rotations in hybrid quantum-classical programs. To support mid-circuit measurements, we design a hardware-based halt-resume protocol that resumes pipeline execution within 80 nsns of receiving the measurement result. Comprehensive evaluation using both RISC-V toolchains and FPGA prototypes demonstrates that our design achieves up to 2.52×\times speedup over the baseline in program execution time, with excellent scalability.

引用

@article{arxiv.2607.07372,
  title  = {Vectorizing Quantum Control: A RISC-V Vector Extension Architecture for Scalable Qubit Systems},
  author = {Xiaorang Guo and Kun Qin and Yanbin Chen and Carsten Trinitis and Martin Schulz},
  journal= {arXiv preprint arXiv:2607.07372},
  year   = {2026}
}

备注

Accepted at IEEE International Conference on Quantum Computing and Engineering (QCE) 2026