English

Qubit-Efficient Quantum Search for Hyperdimensional Decomposition via Logarithmic Encoding

Machine Learning 2026-07-11 v1

Abstract

Hyperdimensional Computing (HDC) represents symbols using high-dimensional hypervectors of dimension DD. In hypervector decomposition, the objective is to recover FF constituent hypervectors, each drawn from a codebook of size NN, from a bound target hypervector. This requires searching over NFN^F candidate tuples, making the task computationally prohibitive at scale. Recent quantum approach provides a quadratic search advantage, but typically rely on qubit-inefficient O(D)O(D)-qubit hypervector representations. We propose a qubit-efficient quantum framework for HDC decomposition that reduces the representation cost to O(logD)O(\log D). The framework introduces logarithmic hypervector and binding encodings, together with a reversible hypervector lookup operator for circuit-level manipulation of dense hypervectors. Combined with a modified D\"urr-H{\o}yer search procedure, the method preserves O(NF)O(\sqrt{N^F}) search complexity while substantially reducing qubit usage. Experimental results validate correct similarity computation, accurate decomposition in executable regimes, and significantly improved qubit scaling over baselines based on explicit DD-qubit hypervector encodings, achieving up to 2,000×2{,}000\times fewer qubits.

Cite

@article{arxiv.2607.11936,
  title  = {Qubit-Efficient Quantum Search for Hyperdimensional Decomposition via Logarithmic Encoding},
  author = {Sanggeon Yun and Hyunwoo Oh and Ryozo Masukawa and Raheeb Hassan and Mohsen Imani},
  journal= {arXiv preprint arXiv:2607.11936},
  year   = {2026}
}

Comments

Accepted to ICCAD 2026