Artificial cognition in production systems

Alexander Bannat; Thibault Bautze; Michael Beetz; Juergen Blume; Klaus Diepold; Christoph Ertelt; Florian Geiger; Thomas Gmeiner; Tobias Gyger; Alois Knoll; Christian Lau; Claus Lenz; Martin Ostgathe; Gunther Reinhart; Wolfgang Roesel; Thomas Ruehr; Anna Schuboe; Kristina Shea; Ingo Stork Genannt Wersborg; Sonja Stork; William Tekouo; Frank Wallhoff; Mathey Wiesbeck; Michael F. Zaeh

doi:10.1109/TASE.2010.2053534

Artificial cognition in production systems

Alexander Bannat, Thibault Bautze, Michael Beetz, Juergen Blume, Klaus Diepold, Christoph Ertelt, Florian Geiger, Thomas Gmeiner, Tobias Gyger, Alois Knoll, Christian Lau, Claus Lenz, Martin Ostgathe, Gunther Reinhart, Wolfgang Roesel, Thomas Ruehr, Anna Schuboe, Kristina Shea, Ingo Stork Genannt Wersborg, Sonja StorkWilliam Tekouo, Frank Wallhoff, Mathey Wiesbeck, Michael F. Zaeh

Research output: Contribution to journal › Article › peer-review

99 Scopus citations

Abstract

Today's manufacturing and assembly systems have to be flexible to adapt quickly to an increasing number and variety of products, and changing market volumes. To manage these dynamics, several production concepts (e.g., flexible, reconfigurable, changeable or autonomous manufacturing and assembly systems) were proposed and partly realized in the past years. This paper presents the general principles of autonomy and the proposed concepts, methods and technologies to realize cognitive planning, cognitive control and cognitive operation of production systems. Starting with an introduction on the historical context of different paradigms of production (e.g., evolution of production and planning systems), different approaches for the design, planning, and operation of production systems are lined out and future trends towards fully autonomous components of an production system as well as autonomous parts and products are discussed. In flexible production systems with manual and automatic assembly tasks, human-robot cooperation is an opportunity for an ergonomic and economic manufacturing system especially for low lot sizes. The state-of-the-art and a cognitive approach in this area are outlined. Furthermore, introducing self-optimizing and self-learning control systems is a crucial factor for cognitive systems. This principles are demonstrated by a quality assurance and process control in laser welding that is used to perform improved quality monitoring. Finally, as the integration of human workers into the workflow of a production system is of the highest priority for an efficient production, worker guidance systems for manual assembly with environmentally- and situationally dependent triggered paths on state-based graphs are described in this paper.

Original language	English
Article number	5524092
Pages (from-to)	148-174
Number of pages	27
Journal	IEEE Transactions on Automation Science and Engineering
Volume	8
Issue number	1
DOIs	https://doi.org/10.1109/TASE.2010.2053534
State	Published - Jan 2011

Keywords

Adaptive control
assembly systems
assistance systems
autonomous processes
cognitive factory
computer aided design
computer aided process planning
computer integrated manufacturing
computer-aided manufacturing
flexible manufacturing systems
human-robot cooperation
manufacturing systems
multi-agent systems
paradigms of production
production planning and control
quality assurance
radio-frequency identification
reconfigurable manufacturing systems

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10.1109/TASE.2010.2053534

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Bannat, A., Bautze, T., Beetz, M., Blume, J., Diepold, K., Ertelt, C., Geiger, F., Gmeiner, T., Gyger, T., Knoll, A., Lau, C., Lenz, C., Ostgathe, M., Reinhart, G., Roesel, W., Ruehr, T., Schuboe, A., Shea, K., Stork Genannt Wersborg, I., ... Zaeh, M. F. (2011). Artificial cognition in production systems. IEEE Transactions on Automation Science and Engineering, 8(1), 148-174. Article 5524092. https://doi.org/10.1109/TASE.2010.2053534

@article{7d58e75b08b8485a959fa3dee0af43d8,

title = "Artificial cognition in production systems",

abstract = "Today's manufacturing and assembly systems have to be flexible to adapt quickly to an increasing number and variety of products, and changing market volumes. To manage these dynamics, several production concepts (e.g., flexible, reconfigurable, changeable or autonomous manufacturing and assembly systems) were proposed and partly realized in the past years. This paper presents the general principles of autonomy and the proposed concepts, methods and technologies to realize cognitive planning, cognitive control and cognitive operation of production systems. Starting with an introduction on the historical context of different paradigms of production (e.g., evolution of production and planning systems), different approaches for the design, planning, and operation of production systems are lined out and future trends towards fully autonomous components of an production system as well as autonomous parts and products are discussed. In flexible production systems with manual and automatic assembly tasks, human-robot cooperation is an opportunity for an ergonomic and economic manufacturing system especially for low lot sizes. The state-of-the-art and a cognitive approach in this area are outlined. Furthermore, introducing self-optimizing and self-learning control systems is a crucial factor for cognitive systems. This principles are demonstrated by a quality assurance and process control in laser welding that is used to perform improved quality monitoring. Finally, as the integration of human workers into the workflow of a production system is of the highest priority for an efficient production, worker guidance systems for manual assembly with environmentally- and situationally dependent triggered paths on state-based graphs are described in this paper.",

keywords = "Adaptive control, assembly systems, assistance systems, autonomous processes, cognitive factory, computer aided design, computer aided process planning, computer integrated manufacturing, computer-aided manufacturing, flexible manufacturing systems, human-robot cooperation, manufacturing systems, multi-agent systems, paradigms of production, production planning and control, quality assurance, radio-frequency identification, reconfigurable manufacturing systems",

author = "Alexander Bannat and Thibault Bautze and Michael Beetz and Juergen Blume and Klaus Diepold and Christoph Ertelt and Florian Geiger and Thomas Gmeiner and Tobias Gyger and Alois Knoll and Christian Lau and Claus Lenz and Martin Ostgathe and Gunther Reinhart and Wolfgang Roesel and Thomas Ruehr and Anna Schuboe and Kristina Shea and {Stork Genannt Wersborg}, Ingo and Sonja Stork and William Tekouo and Frank Wallhoff and Mathey Wiesbeck and Zaeh, {Michael F.}",

note = "Funding Information: Manuscript received December 10, 2009; accepted February 18, 2010. Date of publication July 26, 2010; date of current version January 07, 2011. This paper was recommended for publication by Associate Editor Y. Ma and Editor M. Zhou upon evaluation of the reviewers{\textquoteright} comments. This ongoing work is supported by the DFG Excellence Initiative Research Cluster Cognition for Technical Systems—CoTeSys, see www.cotesys.org for further details.",

year = "2011",

month = jan,

doi = "10.1109/TASE.2010.2053534",

language = "English",

volume = "8",

pages = "148--174",

journal = "IEEE Transactions on Automation Science and Engineering",

issn = "1545-5955",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

number = "1",

}

Bannat, A, Bautze, T, Beetz, M, Blume, J, Diepold, K, Ertelt, C, Geiger, F, Gmeiner, T, Gyger, T, Knoll, A, Lau, C, Lenz, C, Ostgathe, M, Reinhart, G, Roesel, W, Ruehr, T, Schuboe, A, Shea, K, Stork Genannt Wersborg, I, Stork, S, Tekouo, W, Wallhoff, F, Wiesbeck, M & Zaeh, MF 2011, 'Artificial cognition in production systems', IEEE Transactions on Automation Science and Engineering, vol. 8, no. 1, 5524092, pp. 148-174. https://doi.org/10.1109/TASE.2010.2053534

TY - JOUR

T1 - Artificial cognition in production systems

AU - Bannat, Alexander

AU - Bautze, Thibault

AU - Beetz, Michael

AU - Blume, Juergen

AU - Diepold, Klaus

AU - Ertelt, Christoph

AU - Geiger, Florian

AU - Gmeiner, Thomas

AU - Gyger, Tobias

AU - Knoll, Alois

AU - Lau, Christian

AU - Lenz, Claus

AU - Ostgathe, Martin

AU - Reinhart, Gunther

AU - Roesel, Wolfgang

AU - Ruehr, Thomas

AU - Schuboe, Anna

AU - Shea, Kristina

AU - Stork Genannt Wersborg, Ingo

AU - Stork, Sonja

AU - Tekouo, William

AU - Wallhoff, Frank

AU - Wiesbeck, Mathey

AU - Zaeh, Michael F.

N1 - Funding Information: Manuscript received December 10, 2009; accepted February 18, 2010. Date of publication July 26, 2010; date of current version January 07, 2011. This paper was recommended for publication by Associate Editor Y. Ma and Editor M. Zhou upon evaluation of the reviewers’ comments. This ongoing work is supported by the DFG Excellence Initiative Research Cluster Cognition for Technical Systems—CoTeSys, see www.cotesys.org for further details.

PY - 2011/1

Y1 - 2011/1

N2 - Today's manufacturing and assembly systems have to be flexible to adapt quickly to an increasing number and variety of products, and changing market volumes. To manage these dynamics, several production concepts (e.g., flexible, reconfigurable, changeable or autonomous manufacturing and assembly systems) were proposed and partly realized in the past years. This paper presents the general principles of autonomy and the proposed concepts, methods and technologies to realize cognitive planning, cognitive control and cognitive operation of production systems. Starting with an introduction on the historical context of different paradigms of production (e.g., evolution of production and planning systems), different approaches for the design, planning, and operation of production systems are lined out and future trends towards fully autonomous components of an production system as well as autonomous parts and products are discussed. In flexible production systems with manual and automatic assembly tasks, human-robot cooperation is an opportunity for an ergonomic and economic manufacturing system especially for low lot sizes. The state-of-the-art and a cognitive approach in this area are outlined. Furthermore, introducing self-optimizing and self-learning control systems is a crucial factor for cognitive systems. This principles are demonstrated by a quality assurance and process control in laser welding that is used to perform improved quality monitoring. Finally, as the integration of human workers into the workflow of a production system is of the highest priority for an efficient production, worker guidance systems for manual assembly with environmentally- and situationally dependent triggered paths on state-based graphs are described in this paper.

AB - Today's manufacturing and assembly systems have to be flexible to adapt quickly to an increasing number and variety of products, and changing market volumes. To manage these dynamics, several production concepts (e.g., flexible, reconfigurable, changeable or autonomous manufacturing and assembly systems) were proposed and partly realized in the past years. This paper presents the general principles of autonomy and the proposed concepts, methods and technologies to realize cognitive planning, cognitive control and cognitive operation of production systems. Starting with an introduction on the historical context of different paradigms of production (e.g., evolution of production and planning systems), different approaches for the design, planning, and operation of production systems are lined out and future trends towards fully autonomous components of an production system as well as autonomous parts and products are discussed. In flexible production systems with manual and automatic assembly tasks, human-robot cooperation is an opportunity for an ergonomic and economic manufacturing system especially for low lot sizes. The state-of-the-art and a cognitive approach in this area are outlined. Furthermore, introducing self-optimizing and self-learning control systems is a crucial factor for cognitive systems. This principles are demonstrated by a quality assurance and process control in laser welding that is used to perform improved quality monitoring. Finally, as the integration of human workers into the workflow of a production system is of the highest priority for an efficient production, worker guidance systems for manual assembly with environmentally- and situationally dependent triggered paths on state-based graphs are described in this paper.

KW - Adaptive control

KW - assembly systems

KW - assistance systems

KW - autonomous processes

KW - cognitive factory

KW - computer aided design

KW - computer aided process planning

KW - computer integrated manufacturing

KW - computer-aided manufacturing

KW - flexible manufacturing systems

KW - human-robot cooperation

KW - manufacturing systems

KW - multi-agent systems

KW - paradigms of production

KW - production planning and control

KW - quality assurance

KW - radio-frequency identification

KW - reconfigurable manufacturing systems

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U2 - 10.1109/TASE.2010.2053534

DO - 10.1109/TASE.2010.2053534

M3 - Article

AN - SCOPUS:78651075251

SN - 1545-5955

VL - 8

SP - 148

EP - 174

JO - IEEE Transactions on Automation Science and Engineering

JF - IEEE Transactions on Automation Science and Engineering

IS - 1

M1 - 5524092

ER -

Artificial cognition in production systems

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