Performance Measurement System and Quality Management in Data-Driven Industry 4.0: A Review

Tambare, Parkash; Meshram, Chandrashekhar; Lee, Cheng‐Chi; Ramteke, R. J.; Imoize, Agbotiname Lucky

doi:10.3390/s22010224

Cited by 45 publications

(23 citation statements)

References 115 publications

(180 reference statements)

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“…Out of three vertices of a 5G triangle, i.e., enhanced mobile broadband (eMBB), massive machine-type communication (mMTC), and URLLC, the factory automation scenario fits best under URLLC category to ensure millisecond-level delay in smart communication [ 35 , 36 ]. Moreover, with the emergence of ever more sophisticated applications (such as holographic telepresence, virtual reality, augmented reality, visual capabilities for smart robots and automatic guided vehicles, mass customization and personalization of products), the sixth generation of wireless technology (6G) has also emerged as an enabling technology to enhance the efficiency and scalability of the communication system [ 37 , 38 , 39 , 40 , 41 , 42 , 43 , 44 ]. As a result, traditional sub-6 GHz wireless communication cannot meet URLLC requirements of Industry 4.0 and beyond because the unlicensed spectral resources in the low-frequency bands (e.g., 2.4 GHz and 5 GHz) are limited.…”

Section: Introductionmentioning

confidence: 99%

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Millimeter-Wave Smart Antenna Solutions for URLLC in Industry 4.0 and Beyond

Jabbar

Abbasi

Anjum

et al. 2022

Sensors

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Industry 4.0 is a new paradigm of digitalization and automation that demands high data rates and real-time ultra-reliable agile communication. Industrial communication at sub-6 GHz industrial, scientific, and medical (ISM) bands has some serious impediments, such as interference, spectral congestion, and limited bandwidth. These limitations hinder the high throughput and reliability requirements of modern industrial applications and mission-critical scenarios. In this paper, we critically assess the potential of the 60 GHz millimeter-wave (mmWave) ISM band as an enabler for ultra-reliable low-latency communication (URLLC) in smart manufacturing, smart factories, and mission-critical operations in Industry 4.0 and beyond. A holistic overview of 60 GHz wireless standards and key performance indicators are discussed. Then the review of 60 GHz smart antenna systems facilitating agile communication for Industry 4.0 and beyond is presented. We envisage that the use of 60 GHz communication and smart antenna systems are crucial for modern industrial communication so that URLLC in Industry 4.0 and beyond could soar to its full potential.

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Section: Introductionmentioning

confidence: 99%

“…In the context of Industry 4.0 and beyond, the requirements for quality of service (QoS) and quality of data (QoD) are much more stringent [ 28 , 41 ]. QoS mainly includes high reliability, real-time operation, agility, seamless connectivity, security, and privacy.…”

Section: Introductionmentioning

confidence: 99%

Millimeter-Wave Smart Antenna Solutions for URLLC in Industry 4.0 and Beyond

Jabbar

Abbasi

Anjum

et al. 2022

Sensors

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“…is the first gap of industrial needs [12][13][14]. There is no doubt that KPIs have enormous potential as a comparative method of machine performance and, consequently, a tool in monitoring continuous improvement [15].…”

Section: Introductionmentioning

confidence: 99%

Energy Key Performance Indicators for Mobile Machinery

Roquet¹,

Raush

Berne

et al. 2022

Energies

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Mobile machinery manufacturers must face and deal with reducing fuel consumption, rising prices, and environmental pollution. The development of methods to evaluate the efficiency and effectiveness of the energy performance of hydraulically actuated systems has become a priority for researchers and OEMs, Original Equipment Manufacturers. In this paper, a new methodology that is based on Key Performance Indicators, KPI, is proposed with different goals: (i) to evaluate the energy performance and the monitoring of its evolution in the different stages of its life cycle (design, commissioning, optimization, retrofit, etc.); (ii) compare the energy levels between machines of different sizes and different brands in a benchmarking process; and (iii) establish a database that is state of the art, which facilitates setting achievable goals or limits for improvement. These KPI values can be deduced simply from the energy balances that were made from the experimental study of various machines over a relatively long period. This methodology has been applied to typical hydraulic systems for lifting and lowering loads that are used in a wide variety of mobile machines of different mechanical designs and sizes. Still, it can be included in the generic name of “loaders”. A KPI’s values for the three machines are presented in a dashboard as a decision-making tool.

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“…Due to a large number of checkpoints, high sampling rate and long detection time, the health monitoring system has acquired massive status data. On the one hand, it has prompted the fault diagnosis of complex industrial systems to move into the “data-driven” era [ 2 ], on the other hand, it has also brought great difficulty to fast fault diagnosis in resource-constrained industrial embedded systems [ 3 ].…”

Section: Introductionmentioning

confidence: 99%

Fast Fault Diagnosis in Industrial Embedded Systems Based on Compressed Sensing and Deep Kernel Extreme Learning Machines

Shan

Bao

et al. 2022

Sensors

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With the complexity and refinement of industrial systems, fast fault diagnosis is crucial to ensuring the stable operation of industrial equipment. The main limitation of the current fault diagnosis methods is the lack of real-time performance in resource-constrained industrial embedded systems. Rapid online detection can help deal with equipment failures in time to prevent equipment damage. Inspired by the ideas of compressed sensing (CS) and deep extreme learning machines (DELM), a data-driven general method is proposed for fast fault diagnosis. The method contains two modules: data sampling and fast fault diagnosis. The data sampling module non-linearly projects the intensive raw monitoring data into low-dimensional sampling space, which effectively reduces the pressure of transmission, storage and calculation. The fast fault diagnosis module introduces the kernel function into DELM to accommodate sparse signals and then digs into the inner connection between the compressed sampled signal and the fault types to achieve fast fault diagnosis. This work takes full advantage of the sparsity of the signal to enable fast fault diagnosis online. It is a general method in industrial embedded systems under data-driven conditions. The results on the CWRU dataset and real platforms show that our method not only has a significant speed advantage but also maintains a high accuracy, which verifies the practical application value in industrial embedded systems.

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Performance Measurement System and Quality Management in Data-Driven Industry 4.0: A Review

Cited by 45 publications

References 115 publications

Millimeter-Wave Smart Antenna Solutions for URLLC in Industry 4.0 and Beyond

Millimeter-Wave Smart Antenna Solutions for URLLC in Industry 4.0 and Beyond

Energy Key Performance Indicators for Mobile Machinery

Fast Fault Diagnosis in Industrial Embedded Systems Based on Compressed Sensing and Deep Kernel Extreme Learning Machines

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