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Industry 4.0 Vision for the Supply of Energy and Materials


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such as virtual reality for remote maintenance worker assistance and production line imaging for quality inspection significantly benefit from the higher bandwidth available through 5G eMBB. In addition to fast data rate, 5G eMBB provides low latency of 4 ms over the air, enabling real-time data transmission, processing, and decision-making for autonomous warehousing robots and industrial machine control [167]. One approach for providing eMBB is to implement millimeter wave (mm-wave) technology and install high-frequency mm-wave antennas [168].

      1.5.4.3 Massive Machine Type Communication

      1.6 Wireless System Design Enablers and Metrics for Emerging IIoT Applications

      IIoT is one of the key components of the Fourth Industrial Revolution. It provides customized architectures and standardized interfaces for data acquisition, transmission, and analytics in industrial applications [25]. Diverse industrial applications differ in terms of operational settings, technical requirements, and service environments. Therefore, it is not possible to provide one multi-purpose wireless solution for all IIoT use cases. Each wireless system design requires theoretical and experimental measures based on its expected performance. In this section, we first review conventional technical enablers in design of wireless networks for IIoT and then discuss the metrics on the desired performance.

      1.6.1 General Technical Enablers in Design of Wireless Network for IIoT

      The National Institute of Standards and Technology (NIST) proposed a reference framework as a guideline that helps users select and design a given wireless system, customize its configuration based on the specific application requirements, successfully deploy it, and finally ensure its performance for industrial environments [55]. Based on this framework, the design of industrial wireless communication should be evaluated from three major aspects: system modeling and verification, radio resource management (RRM) schemes, and protocol interfaces design.

      1.6.1.1 System Modeling and Verification

      The connectivity in IIoT systems could exploit well-established communication protocols to reduce network configurations and customizations. However, the increasing integration of communication into automation aspects makes IIoT systems more complex and prone to errors (e.g., device failures, mistakes in configuration). Given that failure in communication may be catastrophic in industrial applications using IIoT, it is essential to use proper system models and verification schemes to increase the level of certainty in IIoT systems. There are different approaches to create system models, such as theoretical inference and simulation tests.

      1.6.1.2 Radio Resource Management

      1.6.1.3 Protocol Interface Design

      1.6.2 Metrics for Wireless System Design in IIoT

      The autonomous communication in the future IIoT environment significantly relies on wireless networks. There are different wireless technologies competing with each other for various industrial services and use cases. Since network connectivity should be robust and efficient, crucial challenges are raised in network design and integration of automation and control systems. Furthermore,