Abstract
We describe two proof-of-concept approaches on the sonification of estimated operation states and conditions focusing on two scenarios: a laboratory setup of a manipulated 3D printer and an industrial setup focusing on the operations of a punching machine. The results of these studies form the basis for the development of an “intelligent” noise protection headphone as part of Cyber Physical Production Systems which provides auditorily augmented information to machine operators and enables radio communication between them. Further application areas are implementations in control rooms (equipped with multi-channel loudspeaker systems) and utilization for training purposes. As a first proof-of-concept, the data stream of error probability estimations regarding partly manipulated 3D printing processes were mapped to three sonification models, providing evidence about momentary operation states. The neural network applied indicates a high accuracy (> 93%) of the error estimation distinguishing between normal and manipulated operation states. None of the manipulated states could be identified by listening. An auditory augmentation, or sonification of these error estimations, provides a considerable benefit to process monitoring. For a second proof-of-concept, setup operations of a punching machine were recorded. Since all operations were apparently flawlessly executed, and there were no errors to be reported, we focused on the identification of operation phases. Each phase of a punching process could be algorithmically distinguished at an estimated probability rate of > 94%. In the auditory display, these phases were represented by different instrumentations of a musical piece in order to allow users to differentiate between operations auditorily.
Highlights
A side effect of the transition from traditional production processes to smart manufacturing and Industry 4.0 is a steady increase in complexity regarding the variety and diversity of products to be manufactured and in terms of operating and maintaining production plants in general
Stocker et al suggest application fields for information and communication technology (ICT) solutions based on four potential implementations [2]: 1. the “personalized augmented operator,” which means the support of operators through augmented reality content
[8] indicate the advantages of continuous sonification for process monitoring, since instead of displaying warning sounds only related to specific situations, the auditory display will permanently represent the state of the monitored system
Summary
A side effect of the transition from traditional production processes to smart manufacturing and Industry 4.0 is a steady increase in complexity regarding the variety and diversity of products to be manufactured and in terms of operating and maintaining production plants in general. Due to its comparatively simple implementation in existing infrastructure and the good recognizability of altering sound attributes by means of machine learning, more and more companies supplying automation technology offer machine learning-based methodology as a product for industrial applications, especially in energy, infrastructure, and manufacturing domains These approaches mostly focus on automated, algorithmically classified, and evaluated condition monitoring processes. These facts make AD interesting for smart manufacturing applications, especially for monitoring and controlling operations in production lines and shop floors Based on these considerations about (i) the potential of auditorily enhanced CPPS, (ii) acoustic condition monitoring based on machine learning, and (iii) the importance of auditory feedback for work experience and the buildup of working knowledge [18, 19], we designed a research project that combines these three aspects. After a discussion of the results, we will conclude with an outlook on future steps of our research
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