Online cycle detection for models with mode-dependent input and output dependencies
In the fields of co-simulation and component-based modelling, designers import models as building blocks to create a composite model that provides more complex functionalities. Modelling tools perform instantaneous cycle detection (ICD) on the composite models having feedback loops to reject the...
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| Main Authors: | , , |
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| Other Authors: | |
| Format: | Article |
| Language: | English |
| Published: |
2022
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| Subjects: | |
| Online Access: | https://hdl.handle.net/10356/160438 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | In the fields of co-simulation and component-based modelling, designers
import models as building blocks to create a composite model that provides more
complex functionalities. Modelling tools perform instantaneous cycle detection
(ICD) on the composite models having feedback loops to reject the models if the
loops are mathematically unsound and to improve simulation performance. In this
case, the analysis relies heavily on the availability of dependency information
from the imported models. However, the cycle detection problem becomes harder
when the model's input to output dependencies are mode-dependent, i.e. changes
for certain events generated internally or externally as inputs. The number of
possible modes created by composing such models increases significantly and
unknown factors such as environmental inputs make the offline (statical) ICD a
difficult task. In this paper, an online ICD method is introduced to address
this issue for the models used in cyber-physical systems. The method utilises
an oracle as a central source of information that can answer whether the
individual models can make mode transition without creating instantaneous
cycles. The oracle utilises three types of data-structures created offline that
are adaptively chosen during online (runtime) depending on the frequency as
well as the number of models that make mode transitions. During the analysis,
the models used online are stalled from running, resulting in the discrepancy
with the physical system. The objective is to detect an absence of the
instantaneous cycle while minimising the stall time of the model simulation
that is induced from the analysis. The benchmark results show that our method
is an adequate alternative to the offline analysis methods and significantly
reduces the analysis time. |
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