XL-HD: Extended Learning in Hyperdimensional Computing via Deterministic Projections for In-Memory Accelerators
摘要
Hyperdimensional computing (HDC) is a promising approach for energy-efficient edge machine learning (ML), where low latency, low power, and tight memory budgets are essential. However, traditional HDC relies on symbolic binding and pseudo-random high-dimensional vectors, which require large dimensionality and heuristic updates to reach competitive accuracy, limiting deployment on edge hardware. We introduce XL-HD, a deterministic, projection-based, fully learnable HDC framework tailored for in-memory acceleration within edge computing systems. The method uses a fixed Sobol sequence to project binary inputs, extending learning beyond conventional HDC. During training, class prototypes are optimized in real-valued space and later binarized, enabling an entirely binary dot-product inference pipeline ideal for IMC hardware such as ReRAM crossbars. XL-HD achieves competitive accuracy on MNIST, UCIHAR, and ISOLET while maintaining a compact IMC-based inference engine with area and only per single-cycle inference.
引用
@article{arxiv.2605.24788,
title = {XL-HD: Extended Learning in Hyperdimensional Computing via Deterministic Projections for In-Memory Accelerators},
author = {Sabrina Hassan Moon and Abu Kaisar Mohammad Masum and Sercan Aygun and Dayane Reis},
journal= {arXiv preprint arXiv:2605.24788},
year = {2026}
}
备注
Accepted at The International Symposium on Low Power Electronics and Design (ISLPED) 2026