A Scalable Real-Time SDN-Based MQTT Framework for Industrial Applications
Shahri, E. S.
;
Pedreiras, P.
;
Almeida, L.
ieee open journal of the industrial electronics society Vol. 5, Nº , pp. 215 - 235, , 2024.
ISSN (print):
ISSN (online): 2644-1284
Scimago Journal Ranking: 1,81 (in 2023)
Digital Object Identifier: 10.1109/OJIES.2024.3373232
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Abstract
The increasing prominence of concepts such as Smart Production and Industrial Internet of Things (IIoT) within the context of Industry 4.0 has introduced a new set of requirements for the engineering of industrial systems, including support for dynamic environments, timeliness guarantees, support for heterogeneity, interoperability and reliability. These requirements are further exacerbated at the network level by the notable rise in the number and variety of devices involved. To stay competitive in this ever-changing industrial landscape while boosting productivity, it is vital to meet those requirements, combining established protocols with emerging technologies. Software-Defined Networking (SDN) is the forefront traffic management paradigm that offers flexibility for complex industrial networks, enabling efficient resource allocation and dynamic reconfiguration. Message Queuing Telemetry Transport (MQTT) is a low-overhead protocol of the application layer that is gaining popularity in the scope of the IoT and IIoT. However, its Quality-of-Service (QoS) policies do not support timeliness requirements. This paper presents a framework that seamlessly integrates SDN and MQTT, enhancing network management flexibility while satisfying real-time requirements found in industrial environments. It leverages the User Properties of MQTTv5 to allow specifying real-time requirements. MQTT traffic is intercepted by a Network Manager that extracts real-time information and instructs an SDN controller to deploy corresponding network reservations. MQTT traffic across multiple edge networks is propagated by selected brokers using multicasting. Extensive emulation experiments validate the effectiveness of the proposed approach, demonstrating its superiority over MQTT and Direct Multicast-MQTT (DM-MQTT) in latency reduction. Additionally, a response time analysis is provided and validated experimentally, emphasizing the robust performance of the proposed approach across distinct metrics.