Big Data Analytics for Manufacturing Internet of Things: Opportunities, Challenges and Enabling Technologies (1909.00413v1)

Abstract: The recent advances in information and communication technology (ICT) have promoted the evolution of conventional computer-aided manufacturing industry to smart data-driven manufacturing. Data analytics in massive manufacturing data can extract huge business values while can also result in research challenges due to the heterogeneous data types, enormous volume and real-time velocity of manufacturing data. This paper provides an overview on big data analytics in manufacturing Internet of Things (MIoT). This paper first starts with a discussion on necessities and challenges of big data analytics in manufacturing data of MIoT. Then, the enabling technologies of big data analytics of manufacturing data are surveyed and discussed. Moreover, this paper also outlines the future directions in this promising area.

• The paper demonstrates that big data analytics can optimize smart manufacturing by enhancing operational efficiency and product quality.
• It identifies challenges such as data heterogeneity, integration complexity, and real-time processing demands in the MIoT environment.
• It reviews enabling technologies like RFID, LPWAN, and edge computing, and presents a prototype integrating cloud and edge resources for effective analytics.

Overview of Big Data Analytics for Manufacturing Internet of Things

The paper "Big Data Analytics for Manufacturing Internet of Things: Opportunities, Challenges and Enabling Technologies" presents a comprehensive examination of how the integration of Internet of Things (IoT) and big data analytics is transforming the manufacturing sector, often referred to as Manufacturing Internet of Things (MIoT). This document methodically outlines the opportunities provided by big data analytics in MIoT, identifies the accompanying challenges, and surveys the enabling technologies.

The paper opens by acknowledging the paradigm shift from traditional automated manufacturing to 'smart manufacturing', driven by advances in information and communication technology (ICT). MIoT is characterized by deploying a multitude of sensors, actuators, and devices across the manufacturing environment. These generate vast quantities of heterogeneous data, presenting both opportunities for operational improvement and significant challenges in data management and analysis.

Key Contributions and Findings

The paper articulates several key points regarding big data analytics in MIoT:

1. Necessities and Challenges: It discusses the critical need for analytics in improving factory operations, product quality, supply chain efficiency, and customer experience. However, the real-time, high-volume, and varied nature of MIoT data introduces challenges, including difficulties in data representation, transmission, storage, integration, and redundancy reduction.
2. Enabling Technologies: The paper surveys important technologies facilitating data collection, processing, and analysis:
   • Data Acquisition: Technologies like RFID, LPWAN, and industrial Ethernet are discussed in the context of their advantages and limitations in MIoT data capture.
   • Data Preprocessing and Storage: It examines approaches like data cleaning, integration, and storage solutions including distributed file systems and NoSQL databases.
   • Data Analytics: The paper dives into methods such as statistical modeling, machine learning, predictive and prescriptive analytics, emphasizing their roles at various stages of the manufacturing process.
3. Case Studies and Prototype Implementation: A practical implementation of a prototype system integrating edge and cloud computing is discussed, highlighting how distributed computing can enhance MIoT systems' effectiveness.

Implications and Future Directions

The research provides substantial insights with both theoretical and practical implications. It emphasizes the potential of big data analytics to redefine manufacturing operations by enhancing efficiency and reliability. The paper also suggests areas for future research:

• Security and Privacy: Ensuring data security and privacy in MIoT is crucial. Future work may focus on developing efficient encryption and privacy-preserving analytics suited for the limited computational capacity of IoT devices.
• Edge Computing: Combining edge computing with cloud services provides a pathway to address latency and bandwidth challenges. Developing lightweight analytics suited for edge devices is suggested to leverage this computing paradigm effectively.
• Novel Analytics Methods: The unique challenges of MIoT data, such as imbalance in data classes and continuous data streams, call for innovative analytics methods. Future work could explore adaptive and real-time processing techniques to handle these complexities.

Conclusion

This paper offers a detailed survey of the big data analytics landscape in the context of MIoT. Through a structured approach, it highlights the interplay between opportunities and obstacles within the domain, underscoring the technological advancements necessary to further the efficacy of smart manufacturing processes. The research paves the way for ongoing and future exploration into robust, scalable solutions capable of harnessing the complex data ecosystem within MIoT to achieve significant industrial gains.