TY - JOUR
T1 - A References Architecture for Human Cyber Physical Systems, Part II
T2 - Fundamental Design Principles for Human-CPS Interaction
AU - Bengler, Klaus
AU - Damm, Werner
AU - Luedtke, Andreas
AU - Jochem, Reiger
AU - Austel, Benedikt
AU - Biebl, Bianca
AU - Fränzle, Martin
AU - Hagemann, Willem
AU - Held, Moritz
AU - Hess, David
AU - Ihme, Klas
AU - Kacianka, Severin
AU - Kerscher, Alyssa J.
AU - Forrest, Laine
AU - Lehnhoff, Sebastian
AU - Pretschner, Alexander
AU - Rakow, Astrid
AU - Sonntag, Daniel
AU - Sztipanovits, Janos
AU - Schwammberger, Maike
AU - Schweda, Mark
AU - Unni, Anirudh
AU - Veith, Eric
N1 - Publisher Copyright:
© 2024 Copyright held by the owner/author(s).
PY - 2024/1/14
Y1 - 2024/1/14
N2 - As automation increases qualitatively and quantitatively in safety-critical human cyber-physical systems, it is becoming more and more challenging to increase the probability or ensure that human operators still perceive key artifacts and comprehend their roles in the system. In the companion paper, we proposed an abstract reference architecture capable of expressing all classes of system-level interactions in human cyber-physical systems. Here we demonstrate how this reference architecture supports the analysis of levels of communication between agents and helps to identify the potential for misunderstandings and misconceptions. We then develop a metamodel for safe human machine interaction. Therefore, we ask what type of information exchange must be supported on what level so that humans and systems can cooperate as a team, what is the criticality of exchanged information, what are timing requirements for such interactions, and how can we communicate highly critical information in a limited time frame in spite of the many sources of a distorted perception. We highlight shared stumbling blocks and illustrate shared design principles, which rest on established ontologies specific to particular application classes. In order to overcome the partial opacity of internal states of agents, we anticipate a key role of virtual twins of both human and technical cooperation partners for designing a suitable communication.
AB - As automation increases qualitatively and quantitatively in safety-critical human cyber-physical systems, it is becoming more and more challenging to increase the probability or ensure that human operators still perceive key artifacts and comprehend their roles in the system. In the companion paper, we proposed an abstract reference architecture capable of expressing all classes of system-level interactions in human cyber-physical systems. Here we demonstrate how this reference architecture supports the analysis of levels of communication between agents and helps to identify the potential for misunderstandings and misconceptions. We then develop a metamodel for safe human machine interaction. Therefore, we ask what type of information exchange must be supported on what level so that humans and systems can cooperate as a team, what is the criticality of exchanged information, what are timing requirements for such interactions, and how can we communicate highly critical information in a limited time frame in spite of the many sources of a distorted perception. We highlight shared stumbling blocks and illustrate shared design principles, which rest on established ontologies specific to particular application classes. In order to overcome the partial opacity of internal states of agents, we anticipate a key role of virtual twins of both human and technical cooperation partners for designing a suitable communication.
KW - Cyber-Physical Systems
KW - Human-CPS Interaction
KW - Real-time systems
KW - architecture
KW - interaction design
UR - http://www.scopus.com/inward/record.url?scp=85184749285&partnerID=8YFLogxK
U2 - 10.1145/3622880
DO - 10.1145/3622880
M3 - Article
AN - SCOPUS:85184749285
SN - 2378-962X
VL - 8
JO - ACM Transactions on Cyber-Physical Systems
JF - ACM Transactions on Cyber-Physical Systems
IS - 1
M1 - 3
ER -