Delay compensation of multi-input distinct delay nonlinear systems via neural operators
By: Filip Bajraktari , Luke Bhan , Miroslav Krstic and more
Potential Business Impact:
Makes robots move smoothly despite delays.
In this work, we present the first stability results for approximate predictors in multi-input non-linear systems with distinct actuation delays. We show that if the predictor approximation satisfies a uniform (in time) error bound, semi-global practical stability is correspondingly achieved. For such approximators, the required uniform error bound depends on the desired region of attraction and the number of control inputs in the system. The result is achieved through transforming the delay into a transport PDE and conducting analysis on the coupled ODE-PDE cascade. To highlight the viability of such error bounds, we demonstrate our results on a class of approximators - neural operators - showcasing sufficiency for satisfying such a universal bound both theoretically and in simulation on a mobile robot experiment.
Similar Papers
Delay-adaptive Control of Nonlinear Systems with Approximate Neural Operator Predictors
Systems and Control
Teaches robots to control things with long delays.
Input Delay Compensation for a Class of Switched Linear Systems via Averaging Exact Predictor Feedbacks
Systems and Control
Makes machines switch tasks safely and quickly.
Stabilization of an unstable reaction-diffusion PDE with input delay despite state and input quantization
Systems and Control
Keeps unstable systems stable with delays.