Brain-Inspired Hyperdimensional Computing for Ultra-Efficient Edge AI

Abstract

Hyperdimensional Computing (HDC) is rapidly emerging as an attractive alternative to traditional deep learning algorithms. Despite the profound success of Deep Neural Networks (DNNs) in many domains, the amount of computational power and storage that they demand during training makes deploying them in edge devices very challenging if not infeasible. This, in turn, inevitably necessitates streaming the data from the edge to the cloud which raises serious concerns when it comes to availability, scalability, security, and privacy. Further, the nature of data that edge devices often receive from sensors is inherently noisy. However, DNN algorithms are very sensitive to noise, which makes accomplishing the required learning tasks with high accuracy immensely difficult. In this paper, we aim at providing a comprehensive overview of the latest advances in HDC. HDC aims at realizing real-time performance and robustness through using strategies that more closely model the human brain. HDC is, in fact, motivated by the observation that the human brain operates on high-dimensional data representations. In HDC, objects are thereby encoded with high-dimensional vectors which have thousands of elements. In this paper, we will discuss the promising robustness of HDC algorithms against noise along with the ability to learn from little data. Further, we will present the outstanding synergy between HDC and beyond von Neumann architectures and how HDC opens doors for efficient learning at the edge due to the ultra-lightweight implementation that it needs, contrary to traditional DNNs.