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Adaptive Quantum Homeopathy

Quantum Physics 2025-10-10 v1 Mathematical Physics math.MP

Abstract

Randomness is a fundamental resource in quantum information, with crucial applications in cryptography, algorithms, and error correction. A central challenge is to construct unitary kk-designs that closely approximate Haar-random unitaries while minimizing the costly use of non-Clifford operations. In this work, we present a protocol, named Quantum Homeopathy, able to generate unitary kk-designs on nn qubits, secure against any adversarial quantum measurement, with a system-size-independent number of non-Clifford gates. Inspired by the principle of homeopathy, our method applies a kk-design only to a subsystem of size Θ(k)\Theta(k), independent of nn. This "seed" design is then "diluted" across the entire nn-qubit system by sandwiching it between two random Clifford operators. The resulting ensemble forms an ε\varepsilon-approximate unitary kk-design on nn qubits. We prove that this construction achieves full quantum security against adaptive adversaries using only O~(k2logε1)\tilde{O}(k^2 \log\varepsilon^{-1}) non-Clifford gates. If one requires security only against polynomial-time adaptive adversaries, the non-Clifford cost decreases to O~(k+log1+cε1)\tilde{O}(k + \log^{1+c} \varepsilon^{-1}). This is optimal, since we show that at least Ω(k)\Omega(k) non-Clifford gates are required in this setting. Compared to existing approaches, our method significantly reduces non-Clifford overhead while strengthening security guarantees to adaptive security as well as removing artificial assumptions between nn and kk. These results make high-order unitary designs practically attainable in near-term fault-tolerant quantum architectures.

Keywords

Cite

@article{arxiv.2510.08129,
  title  = {Adaptive Quantum Homeopathy},
  author = {Lennart Bittel and Lorenzo Leone},
  journal= {arXiv preprint arXiv:2510.08129},
  year   = {2025}
}

Comments

5 pages + 14 appendix

R2 v1 2026-07-01T06:26:36.307Z