Unmatched uncertainty mitigation through neural network supported model
predictive control
- URL: http://arxiv.org/abs/2304.11315v1
- Date: Sat, 22 Apr 2023 04:49:48 GMT
- Title: Unmatched uncertainty mitigation through neural network supported model
predictive control
- Authors: Mateus V. Gasparino, Prabhat K. Mishra, Girish Chowdhary
- Abstract summary: We utilize a deep neural network (DNN) as an oracle in the underlying optimization problem of learning based MPC (LBMPC)
We employ a dual-timescale adaptation mechanism, where the weights of the last layer of the neural network are updated in real time.
Results indicate that the proposed approach is implementable in real time and carries the theoretical guarantees of LBMPC.
- Score: 7.036452261968766
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: This paper presents a deep learning based model predictive control (MPC)
algorithm for systems with unmatched and bounded state-action dependent
uncertainties of unknown structure. We utilize a deep neural network (DNN) as
an oracle in the underlying optimization problem of learning based MPC (LBMPC)
to estimate unmatched uncertainties. Generally, non-parametric oracles such as
DNN are considered difficult to employ with LBMPC due to the technical
difficulties associated with estimation of their coefficients in real time. We
employ a dual-timescale adaptation mechanism, where the weights of the last
layer of the neural network are updated in real time while the inner layers are
trained on a slower timescale using the training data collected online and
selectively stored in a buffer. Our results are validated through a numerical
experiment on the compression system model of jet engine. These results
indicate that the proposed approach is implementable in real time and carries
the theoretical guarantees of LBMPC.
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