Qubit-Efficient Quantum Search for Hyperdimensional Decomposition via Logarithmic Encoding
Abstract
Hyperdimensional Computing (HDC) represents symbols using high-dimensional hypervectors of dimension D. In hypervector decomposition, the objective is to recover F constituent hypervectors, each drawn from a codebook of size N, from a bound target hypervector. This requires searching over NF 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)-qubit hypervector representations. We propose a qubit-efficient quantum framework for HDC decomposition that reduces the representation cost to O( 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 Dürr-Høyer search procedure, the method preserves O(NF) 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 D-qubit hypervector encodings, achieving up to 2,000× fewer qubits.
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