Automated Knowledge Graph Learning in Industrial Processes
This work addresses the problem of knowledge extraction for industrial process optimization, though it appears incremental as it builds on existing methods like Granger causality.
The paper tackles the challenge of extracting meaningful relationships from industrial time series data by introducing an automated framework for knowledge graph learning, which improves decision-making and process optimization, as demonstrated in a real-world use case.
Industrial processes generate vast amounts of time series data, yet extracting meaningful relationships and insights remains challenging. This paper introduces a framework for automated knowledge graph learning from time series data, specifically tailored for industrial applications. Our framework addresses the complexities inherent in industrial datasets, transforming them into knowledge graphs that improve decision-making, process optimization, and knowledge discovery. Additionally, it employs Granger causality to identify key attributes that can inform the design of predictive models. To illustrate the practical utility of our approach, we also present a motivating use case demonstrating the benefits of our framework in a real-world industrial scenario. Further, we demonstrate how the automated conversion of time series data into knowledge graphs can identify causal influences or dependencies between important process parameters.