Context-aware controller inference for stabilizing dynamical systems
from scarce data
- URL: http://arxiv.org/abs/2207.11049v1
- Date: Fri, 22 Jul 2022 12:41:53 GMT
- Title: Context-aware controller inference for stabilizing dynamical systems
from scarce data
- Authors: Steffen W. R. Werner, Benjamin Peherstorfer
- Abstract summary: This work introduces a data-driven control approach for stabilizing high-dimensional dynamical systems from scarce data.
The proposed context-aware controller inference approach is based on the observation that controllers need to act locally only on the unstable dynamics to stabilize systems.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: This work introduces a data-driven control approach for stabilizing
high-dimensional dynamical systems from scarce data. The proposed context-aware
controller inference approach is based on the observation that controllers need
to act locally only on the unstable dynamics to stabilize systems. This means
it is sufficient to learn the unstable dynamics alone, which are typically
confined to much lower dimensional spaces than the high-dimensional state
spaces of all system dynamics and thus few data samples are sufficient to
identify them. Numerical experiments demonstrate that context-aware controller
inference learns stabilizing controllers from orders of magnitude fewer data
samples than traditional data-driven control techniques and variants of
reinforcement learning. The experiments further show that the low data
requirements of context-aware controller inference are especially beneficial in
data-scarce engineering problems with complex physics, for which learning
complete system dynamics is often intractable in terms of data and training
costs.
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