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Distributed Deep Convolutional Neural Networks for the Internet-of-Things

Simone Disabato, Manuel Roveri, Cesare Alippi

2021IEEE Transactions on Computers53 citationsDOIOpen Access PDF

Abstract

Severe constraints on memory and computation characterizing the Internet-of-Things (IoT) units may prevent the execution of Deep Learning (DL)-based solutions, which typically demand large memory and high processing load. In order to support a real-time execution of the considered DL model at the IoT unit level, DL solutions must be designed having in mind constraints on memory and processing capability exposed by the chosen IoT technology. In this article, we introduce a design methodology aiming at allocating the execution of Convolutional Neural Networks (CNNs) on a distributed IoT application. Such a methodology is formalized as an optimization problem where the latency between the data-gathering phase and the subsequent decision-making one is minimized, within the given constraints on memory and processing load at the units level. The methodology supports multiple sources of data as well as multiple CNNs in execution on the same IoT system allowing the design of CNN-based applications demanding autonomy, low decision-latency, and high Quality-of-Service.

Topics & Concepts

Computer scienceLatency (audio)Convolutional neural networkComputationDistributed computingDeep learningExecution timeMemory managementParallel computingArtificial neural networkArtificial intelligenceHigh memoryConnectionismDistributed memoryInternet of ThingsOptimization problemData processingRecurrent neural networkStorage managementBig dataKey (lock)Embedded systemComputer engineeringReal-time computingAuxiliary memoryDistributed databaseComputer architectureResponse timeExecution modelRandom access memoryTheoretical computer scienceAdvanced Neural Network ApplicationsIoT and Edge/Fog ComputingBig Data and Digital Economy