Enabling bidirectional real time interaction between biological and technical systems: Structural basics of a control oriented modeling of biology-technology-interfaces

Miehe, Robert; Fischer, Evelyn; Berndt, Dirk; Herzog, Andreas; Horbelt, J.; Full, Johannes; Bauernhansl, Thomas; Schenk, Michael

doi:10.1016/j.procir.2019.03.012

Cited by 21 publications

(11 citation statements)

References 16 publications

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“…Finally, the procurement phase is mainly focused on the application of P4.0 [55, At the Start of Life Cycle Stage, there is more research in the manufacturing and production phase, followed by the design and the procurement phases, as shown in Table 3. The application areas in the manufacturing and production phase include manufacturing [39,79], redistribution manufacturing [53,102], smart manufacturing [103,104], smart mobile products [105], AM [106], and palm oil production industry [50]. The design phase applications encompass smart product development [107], high-rise building design [108], autonomous mobile robots [109], digital bio-economy [110], and urban innovation [111].…”

Section: Life Cycle Stages and Application Areas In Ce And Dementioning

confidence: 99%

Integration of Digital Economy and Circular Economy: Current Status and Future Directions

Liu

Osmani

2021

Sustainability

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Circular economy (CE) is a concept actively advocated by the European Union (EU), China, Japan, and the United Kingdom. At present, CE is considered to grant the most traction for companies to achieve sustainable development. However, CE is still rarely adopted by enterprises. As the backbone of the fourth industrial revolution, the digital economy (DE) is considered to have a disruptive effect. Studies have shown that digital technology has great potential in promoting the development of CE. Especially during the COVID-19 epidemic that has severely negatively affected the global economy, environment, and society, CE and DE are receiving high attention from policy makers, practitioners, and scholars around the world. However, the integration of CE and digital technology is a small and rapidly developing research field that is still in its infancy. Although there is a large amount of research in the fields of CE and DE, respectively, there are few studies that look into integrating these two fields. Therefore, the purpose of this paper is to explore the research progress and trends of the integration of CE and DE, and provide an overview for future research. This paper adopts a bibliometric research method, employs the Web of Science database as its literature source, and uses VOSviewer visual software to carry out keyword co-occurrence analysis, which focuses on publication trends, journal sources, keyword visualization, multidisciplinary areas, life cycle stages, and application fields.

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Section: Life Cycle Stages and Application Areas In Ce And Dementioning

confidence: 99%

Integration of Digital Economy and Circular Economy: Current Status and Future Directions

Liu

Osmani

2021

Sustainability

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“…The main interface components are corresponding sensors and actuators. They are based on electrical, chemical, mechanical or optical principles of action and realize a communication between the biological and technical system [ 10 ]. In this context, biosensors assume a special position as they can be considered an application of a BTI-based system on the one hand, and can also be seen as an enabler of superordinate BTI-based systems on the other.…”

Section: Discussionmentioning

confidence: 99%

“… Odor detection biosensors as examples for biology–technology interface (BTI) systems following Miehe et al [ 10 ]. Biosensors assume a special position as they can be considered as ( a ) an application of a BTI-based system, as well as ( b ) an enabler of a superordinate BTI-based system (i.e., bioreactor with cells that are generating a product).…”

Section: Figurementioning

confidence: 99%

“…This form of systemic interaction enables the creation of self-regulating value-added systems and products, which are summarized under the term biointelligence [ 6 ]. A system or product is considered to be biointelligent if there is a real time exchange of information between biological and technical components [ 10 ]. As part of a comprehensive pilot survey commissioned by the German government with regard to the biological transformation, biosensors were identified as one of the key enabling technologies.…”

Section: Introductionmentioning

confidence: 99%

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Market Perspectives and Future Fields of Application of Odor Detection Biosensors within the Biological Transformation—A Systematic Analysis

et al. 2021

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The technological advantages that biosensors have over conventional technical sensors for odor detection and the role they play in the biological transformation have not yet been comprehensively analyzed. However, this is necessary for assessing their suitability for specific fields of application as well as their improvement and development goals. An overview of biological basics of olfactory systems is given and different odor sensor technologies are described and classified in this paper. Specific market potentials of biosensors for odor detection are identified by applying a tailored methodology that enables the derivation and systematic comparison of both the performance profiles of biosensors as well as the requirement profiles for various application fields. Therefore, the fulfillment of defined requirements is evaluated for biosensors by means of 16 selected technical criteria in order to determine a specific performance profile. Further, a selection of application fields, namely healthcare, food industry, agriculture, cosmetics, safety applications, environmental monitoring for odor detection sensors is derived to compare the importance of the criteria for each of the fields, leading to market-specific requirement profiles. The analysis reveals that the requirement criteria considered to be the most important ones across all application fields are high specificity, high selectivity, high repeat accuracy, high resolution, high accuracy, and high sensitivity. All these criteria, except for the repeat accuracy, can potentially be better met by biosensors than by technical sensors, according to the results obtained. Therefore, biosensor technology in general has a high application potential for all the areas of application under consideration. Health and safety applications especially are considered to have high potential for biosensors due to their correspondence between requirement and performance profiles. Special attention is paid to new areas of application that require multi-sensing capability. Application scenarios for multi-sensing biosensors are therefore derived. Moreover, the role of biosensors within the biological transformation is discussed.

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“…Another technological lever of ultra‐efficient production is the biological transformation or biologicalization, describing the increasing use of materials, structures, processes, principles and organisms of living nature in technology. In the context of industrial value creation, this systematic application of knowledge about biological processes leads to an increasing merge of production, information technology and bio‐technology with the potential to profoundly change future products, manufacturing processes and organizations 74–79. This will increasingly transform the process industry.…”

Section: Design Strategies In the Context Of Ultra‐efficiency For Process Industrymentioning

confidence: 99%

Principles and Design Strategies for Ultra‐efficient Production Systems in the Process Industry

Schutzbach

Full

Kiemel

et al. 2021

Chemie Ingenieur Technik

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A sustainable design of production systems, both within and beyond company boundaries, is essential for the future viability of the process industry. In this context, the concept of ultra‐efficiency has recently been developed, aiming at achieving holistic improvements in the fields of action energy and material efficiency, emission reduction, organization, human and staff, with the goal of establishing a positive impact factory. In this paper, the concept developed mainly for the discrete manufacturing industry is transferred to the process industry. It is put into the scientific sub context and elementary approaches, methods and strategies for factory planning and design of production processes in the process industry are summarized.

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Enabling bidirectional real time interaction between biological and technical systems: Structural basics of a control oriented modeling of biology-technology-interfaces

Cited by 21 publications

References 16 publications

Integration of Digital Economy and Circular Economy: Current Status and Future Directions

Integration of Digital Economy and Circular Economy: Current Status and Future Directions

Market Perspectives and Future Fields of Application of Odor Detection Biosensors within the Biological Transformation—A Systematic Analysis

Principles and Design Strategies for Ultra‐efficient Production Systems in the Process Industry

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