Abstract
The Industrial Internet of things (IIoT), the implementation of IoT in the industrial sector, requires a deterministic, real-time, and low-latency communication response for its time-critical applications. A delayed response in such applications could be life-threatening or result in significant losses for manufacturing plants. Although several measures in the likes of predictive maintenance are being put in place to prevent errors and guarantee high network availability, unforeseen failures of physical components are almost inevitable. Our research contribution is to design an efficient communication prototype, entirely based on internet protocol (IP) that combines state-of-the-art communication computing technologies principles to deliver a more stable industrial communication network. We use time-sensitive networking (TSN) and edge computing to increase the determinism of IIoT networks, and we reduce latency with zero-loss redundancy protocols that ensure the sustainability of IIoT networks with smooth recovery in case of unplanned outages. Combining these technologies altogether brings more effectiveness to communication networks than implementing standalone systems. Our study results develop two experimental IP-based industrial network communication prototypes in an intra-domain transmission scenario: the first one is based on the parallel zero-loss redundancy protocol (PRP) and the second one using the high-availability seamless zero-loss redundancy protocol (HSR). We also highlight the benefits of utilizing our communication prototypes to build robust industrial IP communication networks with high network availability and low latency as opposed to conventional communication networks running on seldom redundancy protocols such as Media Redundancy Protocol (MRP) or Rapid Spanning Tree Protocol (RSTP) with single-point of failure and delayed recovery time. While our two network communication prototypes—HSR and PRP—offer zero-loss recovery time in case of a single network failure, our PRP communication prototype goes a step further by providing an effective redundancy scheme against multiple link failures.
Highlights
The manufacturing industry is diving deep into the current industrial revolution, Industry 4.0 (I40)
On the physical side of the prototype, we implement zero-loss recovery redundancy protocols: Parallel Redundancy Protocol (PRP) and high-availability seamless zero-loss redundancy protocol (HSR) to reduce the risk of communication delays due to hardware failure on physical components such as cables or switches
We integrated the operational principles of zero-loss redundancy protocols PRP and HSR to create robust protection against network downtime due to link and network devices failures
Summary
The manufacturing industry is diving deep into the current industrial revolution, Industry 4.0 (I40). IoT, the IIoT offers various improvements for the industrial world, using advanced technologies such as enhanced automation through cloud computing for energy management, manufacturing, and transportation [10]. Tao (2019) [26] built an intelligent framework for IIoT network called IIoT learning by combining edge computing services with some wireless industrial network technologies such as low-power wide-area network (LPWAN). They integrated smart gateways and sensors accessible via wireless to learn and discover information from various network branches. While TSN and edge computing tends to improve the communication requirement of IIoT applications in the software side of the network, the physical network part remains exposed to unforeseen errors. They created two redundant networks receiving duplicated data from the PRP device to ensure data delivery in case of link failure
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