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OpenHD: A GPU-Powered Framework for Hyperdimensional Computing

Jaeyoung Kang, Behnam Khaleghi, Tajana Rosing, Yeseong Kim

2022IEEE Transactions on Computers29 citationsDOI

Abstract

Hyperdimensional computing (HDC) has emerged as an alternative lightweight learning solution to deep neural networks. A key characteristic of HDC is the great extent of parallelism that can facilitate hardware acceleration. However, previous hardware implementations of HDC seldom focus on GPU designs, which were also inefficient partly due to the complexity of accelerating HDC on GPUs. In this paper, we present OpenHD, a flexible and high-performance GPU-powered framework for automating the mapping of general HDC applications including classification and clustering to GPUs. OpenHD takes advantage of memory optimization strategies specialized for HDC, minimizing the access time to different memory subsystems, and removing redundant operations. We also propose a novel training method to enable data parallelism in HDC training. Our evaluation result shows that the proposed training rapidly achieves the target accuracy, reducing the required training epochs by 4×. With OpenHD, users can deploy GPU-accelerated HDC applications without domain expert knowledge. Compared to the state-of-the-art GPU-powered HDC implementation, our evaluation on NVIDIA Jetson TX2 shows that OpenHD is up to 10.5× and 314× faster for HDC-based classification and clustering, respectively. Compared with non-HDC classification and clustering on GPUs, OpenHD-based HDC is 11.7× and 53× faster at comparable accuracy. OpenHD is available at: <uri xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">https://github.com/UCSD-SEELab/openhd</uri> .

Topics & Concepts

Computer scienceCluster analysisParallel computingParallelism (grammar)Key (lock)Domain (mathematical analysis)Artificial neural networkImplementationSupercomputerComputer architectureArtificial intelligenceComputer engineeringProgramming languageOperating systemMathematicsMathematical analysisFerroelectric and Negative Capacitance DevicesAdvanced Memory and Neural ComputingMXene and MAX Phase Materials