智能自治系统上dnn的有效机载部署

Alexandros Kouris, Stylianos I. Venieris, C. Bouganis
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引用次数: 4

摘要

深度神经网络(dnn)在重大人工智能任务中的表现前所未有,已成为现代自主系统的主要组成部分。无人机、移动机器人和无人驾驶汽车等智能系统的感知、规划和特定应用任务主要基于深度神经网络模型。然而,由于这些应用程序的性质,这些系统需要机载本地处理,以保持其自主性并满足延迟和吞吐量限制。在这方面,DNN工作负载的大量计算和内存需求对它们在可用的机载资源和功率受限的计算平台上的部署构成了重大障碍。本文概述了在算法和硬件设计层面解决现代dnn自主系统系统级挑战的最新方法和硬件架构。从延迟驱动的近似计算技术到高通量混合精度级联分类器,所提出的一系列工作为在机器人和自主系统上部署复杂的深度神经网络模型铺平了道路。
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Towards Efficient On-Board Deployment of DNNs on Intelligent Autonomous Systems
With their unprecedented performance in major AI tasks, deep neural networks (DNNs) have emerged as a primary building block in modern autonomous systems. Intelligent systems such as drones, mobile robots and driverless cars largely base their perception, planning and application-specific tasks on DNN models. Nevertheless, due to the nature of these applications, such systems require on-board local processing in order to retain their autonomy and meet latency and throughput constraints. In this respect, the large computational and memory demands of DNN workloads pose a significant barrier on their deployment on the resource-and power-constrained compute platforms that are available on-board. This paper presents an overview of recent methods and hardware architectures that address the system-level challenges of modern DNN-enabled autonomous systems at both the algorithmic and hardware design level. Spanning from latency-driven approximate computing techniques to high-throughput mixed-precision cascaded classifiers, the presented set of works paves the way for the on-board deployment of sophisticated DNN models on robots and autonomous systems.
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