M4E Research #4: January 2024
A Semantic Approach for Big Data Exploration in Industry 4.0
Abstract: The growing trends in automation, Internet of Things, big data and cloud computing technologies have led to the fourth industrial revolution (Industry 4.0), where it is possible to visualize and identify patterns and insights, which results in a better understanding of the data and can improve the manufacturing process. However, many times, the task of data exploration results difficult for manufacturing experts because they might be interested in analyzing also data that does not appear in pre-designed visualizations and therefore they must be assisted by Information Technology experts. In this paper, we present a proposal materialized in a semantic-based visual query system developed for a real Industry 4.0 scenario that allows domain experts to explore and visualize data in a friendly way. The main novelty of the system is the combined use that it makes of captured data that are semantically annotated first, and a 2D customized digital representation of a machine that is also linked with semantic descriptions. Those descriptions are expressed using terms of an ontology, where, among others, the sensors that are used to capture indicators about the performance of a machine that belongs to a Industry 4.0 scenario have been modeled. Moreover, this semantic description allows to: formulate queries at a higher level of abstraction, provide customized graphical visualizations of the results based on the format and nature of the data, and download enriched data enabling further types of analysis.
Authors: Idoia Berges, Víctor Julio Ramírez-Durán, Arantza Illarramendi
FaultFormer: Pretraining Transformers for Adaptable Bearing Fault Classification
Abstract: The growth of global consumption has motivated important applications of deep learning to smart manufacturing and machine health monitoring. In particular, vibration data offers a rich and reliable source to provide meaningful insights into machine health and predictive maintenance. In this work, we present pretraining and fine-tuning frameworks for identifying bearing faults based on transformer models. In particular, we investigate different tokenization and data augmentation strategies to improve performance and reach state of the art accuracies. Furthermore, we demonstrate masked self-supervised pretraining for vibration signals and its application to low-data regimes, task adaptation, and dataset adaptation. Pretraining is able to improve performance on 10-way bearing classification on scarce, unseen training samples. Transformer models also benefit from pretraining when fine-tuning on fault classes outside of the pretraining distribution. Lastly, pretrained transformers are shown to be able to generalize to a different dataset in a few-shot manner. This introduces a new paradigm where models can be pretrained across different bearings, faults, and machinery and quickly deployed to new, data-scarce applications to suit specific manufacturing needs.
Authors: Anthony Zhou, Amir Barati Farimani
Link: https://arxiv.org/abs/2312.09348
Resource Allocation of Industry 4.0 Micro-Service Applications across Serverless Fog Federation
Abstract: The Industry 4.0 revolution has been made possible via AI-based applications (e.g., for automation and maintenance) deployed on the serverless edge (aka fog) computing platforms at the industrial sites -- where the data is generated. Nevertheless, fulfilling the fault-intolerant and real-time constraints of Industry 4.0 applications on resource-limited fog systems in remote industrial sites (e.g., offshore oil fields) that are uncertain, disaster-prone, and have no cloud access is challenging. It is this challenge that our research aims at addressing. We consider the inelastic nature of the fog systems, software architecture of the industrial applications (micro-service-based versus monolithic), and scarcity of human experts in remote sites. To enable cloud-like elasticity, our approach is to dynamically and seamlessly (i.e., without human intervention) federate nearby fog systems. Then, we develop serverless resource allocation solutions that are cognizant of the applications' software architecture, their latency requirements, and distributed nature of the underlying infrastructure. We propose methods to seamlessly and optimally partition micro-service-based application across the federated fog. Our experimental evaluation express that not only the elasticity is overcome in a serverless manner, but also our developed application partitioning method can serve around 20% more tasks on-time than the existing methods in the literature.
Authors: Razin Farhan Hussain, Mohsen Amini Salehi