Design

Applied Knowledge and Augmented Reality

Applied Knowledge and Augmented Reality

Bridging the gap between learning and application
Jana Gonnermann-Müller ORCID Icon, Philip Wotschack, Martin Krzywdzinski ORCID Icon, Norbert Gronau ORCID Icon
The increasing complexity of industrial environments demands new competencies from workers, particularly the ability to interact with advanced digital systems. Traditional training methods often fall short in supporting the effective transfer of applied knowledge to such contexts, and the effectiveness of this transfer, as measured by performance-based outcomes, remains to be investigated. To address this gap, the present study employed a between-subjects experimental design comparing augmented reality- and paper-based instructions within a realistic production training scenario. The results show that participants who learned with augmented reality completed the production process significantly faster and with fewer errors than those using paper instructions. In addition, learners using augmented reality reported higher usability and experienced lower cognitive load during training. These findings suggest that augmented reality can enhance the transfer of practical skills in industrial ...
Industry 4.0 Science | Volume 41 | 2025 | Edition 5 | Pages 22-29 | DOI 10.30844/I4SE.25.5.22
AI-Based Recommender Systems in Product Development

AI-Based Recommender Systems in Product Development

A framework for knowledge discovery from multimodal data in industrial applications
Sebastian Kreuter ORCID Icon, Philipp Besinger, Alexander Lichtenberg, Fazel Ansari, Wilfried Sihn
The engineer-to-order (ETO) production approach is gaining relevance in response to increasing demand for individualized products and small batch sizes. However, ETO inherently reduces the economies of scale typically achieved in series production, as each order requires tailored engineering and production steps. This loss of efficiency can be mitigated through demand-driven and context-aware information provision throughout the product development process. A recommendation system based on semantic artificial intelligence (AI) and machine learning can support this by i) analyzing historical data and prior knowledge, for example drawings or a bill of materials from previous projects, and ii) making automated suggestions, like reusing existing designs or proposing design alternatives, thus compensating for the aforementioned effects.
Industry 4.0 Science | Volume 41 | 2025 | Edition 5 | Pages 94-101 | DOI 10.30844/I4SE.25.5.94
Towards Human-Centered Industrial AI Adoption

Towards Human-Centered Industrial AI Adoption

A reference architecture for machine vision demonstrators
Bernd Kuhlenkötter ORCID Icon
Despite its potential, the introduction of artificial intelligence (AI) in industry is often delayed, primarily due to perceived complexity, high costs, and a lack of expertise. This article presents a modular demonstrator reference architecture that provides practical, low-cost access to industrial AI applications. Developed within a design science research approach, it specifically supports experimentation, learning, and gradual integration into existing production processes. The focus is on machine vision, implemented using cost-effective hardware and open-source software. Its applicability is demonstrated in three scenarios: quality control, chip classification, and in-company training. Initial evaluations confirm the technical feasibility, didactic relevance, and transferability to a variety of industrial contexts.
Industry 4.0 Science | Volume 41 | 2025 | Edition 5 | Pages 152-160 | DOI 10.30844/I4SE.25.5.146
Biomechanical Simulation Pipeline for Exoskeletons

Biomechanical Simulation Pipeline for Exoskeletons

A digital tool for the targeted development of support systems
Robert Eberle ORCID Icon, Maximilian Ebenbichler ORCID Icon, Benjamin Reimeir ORCID Icon, Lennart Ralfs ORCID Icon, Robert Weidner ORCID Icon
Support systems like exoskeletons can reduce physical strain on workers in industrial workplaces. To facilitate their development, a simulation pipeline was created. This pipeline employs musculoskeletal human models coupled with an exoskeleton model, enabling detailed analyses of the biomechanical interaction between humans and exoskeletons. By implementing exoskeleton structures and integrating them into existing musculoskeletal models, the pipeline aims to optimize exoskeleton development while simultaneously enhancing their biomechanical effectiveness.
Industry 4.0 Science | Volume 41 | 2025 | Edition 5 | Pages 30-36 | DOI 10.30844/I4SE.25.5.30
Frameworks for the Structural Integration of Artificial Intelligence

Frameworks for the Structural Integration of Artificial Intelligence

Comparing organizational approaches
Sascha Stowasser
Artificial intelligence is increasingly implemented in companies, but often without clear organizational anchoring. This article evaluates centralized, decentralized, hybrid, and project-based frameworks for the structural integration of artificial intelligence in corporate organizations. A decision table provides guidance for selecting suitable models. In the conclusion, further open research questions are posed.
Industry 4.0 Science | Volume 41 | 2025 | Edition 5 | Pages 144-151 | DOI 10.30844/I4SE.25.5.138
Assistance for Simulation in Production and Logistics

Assistance for Simulation in Production and Logistics

A literature-based classification
Sigrid Wenzel ORCID Icon, Felix Özkul, Robin Sutherland ORCID Icon
Despite the commercial availability of simulation tools, using of discrete-event simulation for complex production and logistics systems is becoming increasingly challenging. It requires extensive expertise, high data quality, and considerable time and financial resources. For many years, therefore, there has been high demand for methodological and organizational support for the conduction of simulation studies. This article is based on an analysis of relevant publications and aims to classify previous research on improving the use of simulation. It also raises the question of the need for assistance in applying discrete event simulation and identifies areas for action.
Industry 4.0 Science | Volume 41 | 2025 | Edition 5 | Pages 66-76 | DOI 10.30844/I4SE.25.5.64
Camera-Based Ergonomics Assessment

Camera-Based Ergonomics Assessment

Developing a method for use in manual assembly
Jannik Liebchen ORCID Icon, Burak Vur, Michael Freitag ORCID Icon
Targeted ergonomic design of workplaces and processes can counteract the challenges of manual assembly and improve working conditions. However, current expert ergonomics assessments are time-consuming and resource-intensive. This article presents an automated assessment method based on the Rapid Upper Limb Assessment (RULA). Results from a laboratory study within an assembly scenario are consistent with expert evaluations.
Industry 4.0 Science | Volume 41 | 2025 | Edition 5 | Pages 120-126 | DOI 10.30844/I4SE.25.5.116
Human-Centered AI-Paired Work Systems

Human-Centered AI-Paired Work Systems

Integrating GenAI and the human factor in work system theory
Katharina Hölzle ORCID Icon, Udo-Ernst Haner
The work system is the key unit of analysis within the discipline of human factors/ergonomics (HFE); it is also considered a fundamental element for value creation within other domains. Its concept is based on sociotechnical systems theory and, within HFE, it conveys a distinctly human-centered perspective. So far, work system models have focused on one or several people working within a defined setting as the only (intelligent) actors within the system. The introduction of generative artificial intelligence (genAI) into work systems, particularly as an intelligent and autonomous actor (agent) with potentially specific social abilities and personality traits, calls for reconceptualization. This article elaborates on the new requirements related to the introduction of genAI and develops a human-centered AI-paired work system model that recognizes the significantly expanded capabilities of AI-enabled collaborative social robots.
Industry 4.0 Science | Volume 41 | 2025 | Edition 5 | Pages 38-48 | DOI 10.30844/I4SE.25.5.38
Empathic Assembly Assistance

Empathic Assembly Assistance

Combining AI-based data analysis and empathic human digital twins
Joachim Lentes, Christian Saba-Gayoso, Matthias Lück ORCID Icon, Katharina Hölzle ORCID Icon
Industrial companies in Germany face demographic change and stagnating productivity in an increasingly complex world. Manual assembly remains essential for complex, low-volume products, yet productivity and quality lag due to human variability. This paper introduces a concept and demonstrator for an empathic assembly assistance system that merges a human digital twin and AI-based screwdriver data analytics within a modular architecture. Tightening anomalies are classified, linked to inferred worker states and translated into information and recommendations.
Industry 4.0 Science | Volume 41 | 2025 | Edition 5 | Pages 6-13 | DOI 10.30844/I4SE.25.5.6
AI Smart Workstation for Industrial Quality Control

AI Smart Workstation for Industrial Quality Control

Enhancing productivity through vision systems, real-time assistance, and Axiomatic Design
Leonardo Venturoso ORCID Icon, Simone Garbin ORCID Icon, Dieter Steiner, Dominik T. Matt
Traditional quality control often falls short in high-mix, low-volume production environments due to variability and complexity. This project introduces an advanced workstation to boost industrial productivity and quality, developed with Axiomatic Design to ensure a clear link between customer needs, functional requirements, and design solutions. Combining polarization cameras, high-resolution imaging, adaptive lighting, and deep learning-based computer vision, the system performs high-accuracy inspection on quantity, quality, and compliance. A digital assistance system offers real-time feedback via an intuitive interface. Validation in a controlled environment confirmed both the system’s practical benefits and its scalability.
Industry 4.0 Science | Volume 41 | 2025 | Edition 5 | Pages 128-134 | DOI 10.30844/I4SE.25.5.124
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