具有神经形态基元的通用数据流模型

Weihao Zhang, Yu Du, Hongyi Li, Songchen Ma, Rong Zhao
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引用次数: 0

摘要

神经形态计算在神经网络以外的各种应用中展现出提供高性能优势的巨大潜力。然而,要弥合程序通用性与神经形态硬件效率之间的差距,需要一种符合神经形态计算特点的通用程序执行模型。数据流模型提供了一种潜在的解决方案,但它在处理控制流程序时面临着高图形复杂性和与神经形态硬件不兼容的问题,从而降低了可编程性和性能。在这里,我们提出了一种为神经形态硬件量身定制的数据流模型,称为神经形态数据流,它为控制逻辑提供了一种紧凑、简洁、与神经形态兼容的程序表示法。神经形态数据流引入了 "when"(何时)和 "where"(何地)原语,重新构建了控制视图。神经形态数据流在数据流模式中嵌入了这些基元,并继承了尖峰算法的可塑性。我们的方法可以在神经形态硬件上部署通用程序,同时兼具可编程性和可塑性,充分发挥硬件的潜力。
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General-purpose Dataflow Model with Neuromorphic Primitives
Neuromorphic computing exhibits great potential to provide high-performance benefits in various applications beyond neural networks. However, a general-purpose program execution model that aligns with the features of neuromorphic computing is required to bridge the gap between program versatility and neuromorphic hardware efficiency. The dataflow model offers a potential solution, but it faces high graph complexity and incompatibility with neuromorphic hardware when dealing with control flow programs, which decreases the programmability and performance. Here, we present a dataflow model tailored for neuromorphic hardware, called neuromorphic dataflow, which provides a compact, concise, and neuromorphic-compatible program representation for control logic. The neuromorphic dataflow introduces "when" and "where" primitives, which restructure the view of control. The neuromorphic dataflow embeds these primitives in the dataflow schema with the plasticity inherited from the spiking algorithms. Our method enables the deployment of general-purpose programs on neuromorphic hardware with both programmability and plasticity, while fully utilizing the hardware's potential.
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