Virtualizing AI at the Distributed Edge towards Intelligent IoT Applications

Campolo, Claudia; Genovese, Giacomo; Molinaro, Antonella

doi:10.3390/jsan10010013

Cited by 16 publications

(5 citation statements)

References 33 publications

(43 reference statements)

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“…In [142] a virtualization layer hosted at the network edge is proposed, which is in charge of the semantic description of AI-embedded IoT devices' capabilities. The virtual replicas expose and augment the cognitive capabilities of the corresponding (potentially constrained) physical devices, in order to feed intelligent IoT applications.…”

Section: ) State-of-the-artmentioning

confidence: 99%

Network for Distributed Intelligence: a Survey and Future Perspectives

Campolo

Molinaro

2023

IEEE Access

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To keep pace with the explosive growth of Artificial Intelligence (AI) and Machine Learning (ML)-dominated applications, distributed intelligence solutions are gaining momentum, which exploit cloud facilities, edge nodes and end-devices to increase the overall computational power, meet application requirements, and optimize performance. Despite the benefits in terms of data privacy and efficient usage of resources, distributing intelligence throughout the cloud-to-things continuum raises unprecedented challenges to the network design. Distributed AI/ML components need high-bandwidth, low-latency connectivity to execute learning and inference tasks, while ensuring high-accuracy and energy-efficiency. This paper aims to explore the new challenging distributed intelligence scenario by extensively and critically scanning the main research achievements in the literature. In addition, starting from them, the main building blocks of a network ecosystem that can enable distributed intelligence are identified and the authors' views are dissected to provide guidelines for the design of a ''future network for distributed Intelligence''.

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Section: ) State-of-the-artmentioning

confidence: 99%

Network for Distributed Intelligence: a Survey and Future Perspectives

Campolo

Molinaro

2023

IEEE Access

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“…Social Object Relationships (SOR) is established due to sporadic or continuous contact of users/devices. The virtualization layer is responsible for hosting the digital counterparts of physical devices [26], i.e., the SDTs. They offer the typical functionalities a digital counterpart provides, including caching and aggregation of the raw data transmitted by the IoT device, before IoT applications can process them.…”

Section: The Siot-edge Framework: An Overviewmentioning

confidence: 99%

Placement of Social Digital Twins at the Edge for Beyond 5G IoT Networks

Chukhno

Araniti

et al. 2022

IEEE Internet Things J.

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As the fifth-generation (5G) and beyond (5G+/6G) networks move forward, and a wide variety of new advanced Internet of Things (IoT) applications are offered, effective methodologies for discovering time-relevant information, services, and resources are being demanded. To this end, computing-, storage-, and battery-constrained IoT devices are progressively augmented via digital twins (DTs) hosted on edge servers. According to recent research results, a further feature these devices may acquire is social behavior; this latter offers enormous possibilities for fast and trustworthy service discovery, although it requires new orchestration policies of DTs at the network edge. This work addresses the dynamic placement of DTs with social capabilities (Social Digital Twins, SDTs) at the edge, by providing an optimal solution under IoT device mobility and by accounting for edge network deployment specifics, types of devices, and their social peculiarities. The optimization problem is formulated as a particular case of the quadratic assignment problem (QAP); also, an approximation algorithm is proposed and two relaxation techniques are applied to reduce computation complexity. Results show that the proposed placement policy ensures a latency among SDTs up to 1.4 times lower than the one obtainable with a traditional proximity-based only placement, while still guaranteeing appropriate proximity between physical devices and their virtual counterparts. Moreover, the proposed heuristic closely approximates the optimal solution while guaranteeing the lowest computational time.

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“…These solutions are traditionally implemented using a centralised approach, in which IoT sensing nodes collect raw data to be streamed to a concentrator that acts as a gateway, and a remote cloud or another edge device with high processing capacity performs compute-intensive tasks, such as AI model training and inference (Ramos et al, 2019). Although centralisation has the advantage of storing the results of the inference stage and can be later requested by other applications without re-running the computation (Campolo et al, 2021), the vast use of certain central edge nodes with parallelism degree and multiple convolution cores, such as Graphics Processing Units (GPU), are not appropriate for resource-constrained IoT architectures (Shafique et al, 2018). Given this situation, other alternatives are being evaluated with the direct intervention of local nodes in data processing, such as concurrent computing (Shi et al, 2016) and fog computing, acting as a medium layer with fog devices of limited storage and computing capabilities, which collect the data offloaded by IoT sensing devices and decide whether to process it locally or offload to the cloud layer via a fog gateway (Ogundoyin and Kamil, 2023).…”

Section: Introductionmentioning

confidence: 99%

Comparison of edge computing methods in Internet of Things architectures for efficient estimation of indoor environmental parameters with Machine Learning

Gamazo-Real,

Torres Fernández,

Murillo Armas

2023

Engineering Applications of Artificial Intelligence

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Virtualizing AI at the Distributed Edge towards Intelligent IoT Applications

Cited by 16 publications

References 33 publications

Network for Distributed Intelligence: a Survey and Future Perspectives

Network for Distributed Intelligence: a Survey and Future Perspectives

Placement of Social Digital Twins at the Edge for Beyond 5G IoT Networks

Comparison of edge computing methods in Internet of Things architectures for efficient estimation of indoor environmental parameters with Machine Learning

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