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Institut / FIR-Bereiche
Methods of machine learning (ML) are difficult for manufacturing companies to employ productively. Data science is not their core skill, and acquiring talent is expensive. Automated machine learning (Auto-ML) aims to alleviate this, democratizing machine learning by introducing elements such as low-code or no-code functionalities into its model creation process. Due to the dynamic vendor market of Auto-ML, it is difficult for manufacturing companies to successfully implement this technology. Different solutions as well as constantly changing requirements and functional scopes make a correct software selection difficult. This paper aims to alleviate said challenge by providing a longlist of requirements that companies should pay attention to when selecting a solution for their use case. The paper is part of a larger research effort, in which a structured selection process for Auto-ML solutions in manufacturing companies is designed. The longlist itself is the result of six case studies of different manufacturing companies, following the method of case study research by Eisenhardt. A total of 75 distinct requirements were identified, spanning the entire machine learning and modeling pipeline.
5G offers the manufacturing industry a wireless, fast and secure transmission technology with high range, low latency and the ability to connect a large number of devices. Existing transmission technologies are reaching their limits due to the increasing number of networked devices and high demands on reliability, data volume, security and latency. 5G fulfills these requirements and also combines the potential and use cases of previous transmission technologies so that unwanted isolated solutions can be merged. Use cases of transmission technologies that previously required a multitude of solutions can now be realized with a single technology. However, the general literature often refers to 5G use cases that can also be realized over cables in particular. In this paper, a literature review presents the current state of research on the various 5G application scenarios in production . Furthermore, concrete characteristics of 5G use cases are identified and assigned to the identified application scenarios. The goal is to verify the identified 5G use cases and to work out their 5G relevance in order to be able to concretely differentiate them from already existing Industrie 4.0 applications.
Feeding the growing world population is a scientific and economic challenge. The target variables to be optimised are the yield that can be produced on a given area and the reduction of the resources used for this purpose. High-wage countries are faced with the problem that the use of personnel is a significant cost driver. Developing countries, on the other hand, usually operate on much smaller field sizes, so that the work in the field is still strongly characterised by manual labour. One solution to meet these challenges is the use of smaller autonomous harvesting robots. These can be networked into a swarm of machines to work even larger fields. The networking of autonomous agricultural machines is a key use case for rural 5G networks. 5G technology can offer many advantages over older mobile communications standards and therefore make use cases more efficient or enable new ones. Various use cases are also conceivable in the field of agriculture, yet it is unclear how 5G networks can and must be specified for this purpose. In this paper, using the example of 5G-connected harvesters powered by swarm robotics, we present the challenges that have arisen and the specification that has been developed.
In road haulage, transports are interrupted by truck drivers to comply with driving and rest times. On long-distance routes, these interruptions lead to a considerable increase in transport time. Transport interruption can be avoided by so-called relay traffic: a vehicle (e. g. semi-trailer) is handed over to a rested driver at the end of the driving time. This type of transport requires a certain company size. In Germany, however, transport companies have 11 employees on average. Intra-company relay traffic is therefore not economically viable for most transport companies. To organize an intermodal transport across forwarding companies, long-distance routes need to be split into partial routes to divide them between freight forwarders and carriers. This paper presents a data concept for an algorithm to find the best possible route sections along a previously defined start and endpoint. The developed data concept includes order-specific data, forwarder-specific data, real-time traffic data, geographical data as well as data from freight forwarding software and telematics to be the basis for the route sectioning algorithm. In this paper, different data sources, external services and logistic systems are analyzed and evaluated. It is shown which data is needed and what the best ways are to select and derive this data from the different data sources.
Digital technologies have gained significant importance in the course of the 4th Industrial Revolution and these technologies are widely implemented, nowadays. However, it is necessary to bear in mind that an ill-considered use can quickly have a negative impact on the environment in which the technology is used. For more responsible and sustainable use, the regulation of digital technologies is therefore necessary today. Since the government is taking a very slow response, as the example of the AI Act shows, companies need to take action themselves today. In this context, one of the central questions for companies is: "Which digital technologies are relevant for manufacturing companies in terms of regulation? This paper conducted a quantitative Delphi study to answer this question. The results of the Delphi study are presented and evaluated within the framework of a data analysis. In addition, it will be discussed how to proceed with the results so that manufacturing companies can benefit from them. Furthermore, the paper contributes to the development of an AI platform in the German research project PAIRS by investigating the compliance relevance of artificial intelligence applications.
Networked digitalisation as an enabler for smart products and data-based business models presents companies with numerous and diverse challenges on their way through the digital transformation. Various reference architecture models have been developed in recent years to support these companies. A detailed analysis of these and in particular their use by companies quickly showed that currently existing reference models have major weaknesses in their practical suitability. With the Aachen Digital Architecture Management (ADAM), a framework was developed that specifically addresses the weaknesses of existing reference architectures and specifically takes up their strengths. As a holistic model, specially developed for use by companies, ADAM structures the digital transformation of companies in the areas of digital infrastructure and business development starting from customer requirements. Systematically, companies are enabled to drive the design of the digital architecture, taking into account design fields. The description of the design fields offers a detailed insight into the essential tasks on the way to a digitally networked company. The model is not only a structuring aid, but also contains a construction kit with the design fields to configure the procedure in the digital transformation. The procedure differentiates between the development of the digitalisation strategy and the implementation of the digital architecture. Three different case studies also show how ADAM is used in industry, what structuring support it can provide and how the digital transformation can be configured. The breadth and depth of ADAM enable companies to take the path of digital transformation systematically and in a structured manner, without ignoring the value-creating components of digitalisation. This qualifies ADAM as a sustainability-oriented framework, as it places the economic scaling, needs-based adaptation and future-oriented robustness of solution modules in the focus of digital transformation.
Der Technologie- und Trendradar 2022 enthält die neusten Technologien und Trends des vergangenen Jahres. Im aktualisierten Radar wurden die Technologiereifegrade in den Steckbriefen neu bewertet, die Anwendungen, Potenziale und Herausforderungen der Technologien wo nötig aktualisiert und neue Technologien aufgenommen.
Der Technologie- und Trendradar 2022 enthält elf neue Steckbriefe. Das Technologiefeld Vernetzung wurde um Eventgetriebene IT-Architekturen, Internet of Behaviors und Web3 erweitert. Dem Feld Virtualisierung wurde die Technologie Metaverse hinzugefügt. Das Technologiefeld Datenverarbeitung wurde um den Trend Data-Centric AI ergänzt, das Feld Prozesse um den Trend Digitale Souveränität. Im Technologiefeld Produkte wurden die Technologien Edge AI, Inter Planetary File System (IPFS), Photonische Siliziumchips, Soft-Robotik und Neuromorphic Computing aufgenommen.
Technologiefrüherkennung
(2022)
Unter Technologiefrüherkennung wird im Folgenden die gezielte Auseinandersetzung mit dem Technologiemarkt und unternehmensspezifischen Anwendungsfällen verstanden. Der Technologieeinsatz kann für Unternehmen entscheidend sein, um ihre Strategie, z. B. die Kostenführerschaft, erfolgreich zu verfolgen. Gleichzeitig können neue Technologien, wie z. B. der 3D-Druck, Markteintrittsbarrieren senken, sodass die Gefahr besteht, dass neue Wettbewerber in den Markt eintreten. Die vernetzte Digitalisierung profitiert unter anderem davon, dass (Informations-)Technologien günstiger und performanter werden. Durch diesen Trend empfiehlt es sich, den sich stetig ändernden Technologiemarkt im Blick zu behalten und eine Übersicht über relevante Technologien zu schaffen. Im folgenden Kapitel werden Methoden vorgestellt, mit denen dieser Überblick gezielt erreicht werden kann. (Quelle: https://link.springer.com/chapter/10.1007/978-3-662-63758-6_13)
This paper addresses the challenge of modelling individual cyber-physical systems (CPS) for small and medium-sized enterprises (SMEs) in manufacturing industries. CPS are key technology building blocks for the implementation of Industrie 4.0. Especially for SMEs the increase of production efficiency and reduction of manufacturing costs through CPS offer potential to maintain their competitiveness and innovation capacity. Although SMEs perceive the potential of CPS, they often lack financial and human resources to acquire the necessary CPS-competencies as well as an overview of all the currently available technological solutions. To overcome this issue a matching platform will offer SMEs support in finding suitable CPS-components by letting them express their functional and technical requirements. The matching logic is based on a set of morphologies that encompasses the functional and requirement spectrum of CPS-components. The matching algorithm analyses the input for congruence of requirements and available technologies and suggests suitable technology combinations. This paper describes the methodology of the matching platform, and introduces the research work to define and to develop the technology morphologies. The presented results facilitate the selection and configuration of CPS for SMEs.
Eine Herausforderung für produzierende Unternehmen in der Entwicklung intelligenter Produkte besteht darin, dass die Zielstellung, die mit einem intelligenten Produkt verfolgt wird, nicht expliziert ist. Zudem ist oftmals nicht spezifiziert, in welchem Anwendungsfall ein intelligentes Produkt agieren soll. Produzierende Unternehmen benötigen Unterstützung, um eine zielorientierte und folglich wirtschaftliche Melioration existierender Produkte zu gewährleisten. Ebendiese Melioration wird im Kontext von intelligenten Produkten als Smartifizierung bezeichnet und stellt damit einen Entwicklungsprozess dar, der ein bestehendes Produkt als Ausgangssituation im Sinne einer Anpassungskonstruktion expliziert. Die originäre Produktfunktion wird folglich nicht verändert, sondern das Produkt um digitale Funktionen und Dienstleistungen erweitert. Der Artikel befasst sich daher erstens mit der Beschreibung generischer Ziele für den Einsatz intelligenter Produkte im Maschinenbau. Eine Zusammenstellung und Erläuterung solcher Ziele unterstützt Unternehmen, eine Präzisierung der Zielfestlegung in der Initiierungsphase eines Smartifizierungsprojekts durchzuführen. Zweitens wird unter Anwendung der Ziel-Mittel-Beziehung ein Anwendungsfall intelligenter Produkte beschrieben. Abschließend werden beide Aspekte in einer Methode zusammengefasst, wie mittels Ziel- und Anwendungsfallbetrachtung Anforderungen abgeleitet und wie diese Elemente in Vorgehensmodelle der Produktentwicklung eingebettet werden können. Exemplarisch wird anhand einer Stanzmaschine aufgezeigt wie die Methode und die sich daraus ableitenden Ergebnisse im Smartifizierungsprozess zur Entwicklung einer intelligenten Stanzmaschine eingesetzt werden.