Unknown nonlinear dynamics can limit the performance of model-based feedforward control. The aim of this paper is to develop a feedforward control framework for systems with unknown, typically nonlinear, dynamics. To address the unknown dynamics, a physics-based feedforward model is complemented by a neural network. The neural network output in the subspace of the model is penalized through orthogonal projection. This results in uniquely identifiable model coefficients, enabling increased performance and similar task flexibility with respect to the model-based controller. The feedforward framework is validated on a representative system with performance limiting nonlinear friction characteristics
An increasing trend in the use of neural networks in control systems is being observed. The aim of t...
This paper considers model-based feedforward for motion systems. The proposed feedforward controller...
Performance of model–based feedforward controllers is typically limited by the accuracy of the model...
Unknown nonlinear dynamics can limit the performance of model-based feedforward control. The aim of ...
Unknown nonlinear dynamics often limit the tracking performance of feedforward control. The aim of t...
The increasing demand on precision and throughput within high-precision mechatronics industries requ...
The improvements in tracking performance resulting from inversion-based feedforward controllers are ...
The performance of a feedforward controller is primarily determined by the extent to which it can ca...
Advanced feedforward control methods enable mechatronic systems to perform varying motion tasks with...
An artificial feedforward neural network is used for on-line control purposes of a class of single i...
The performance of a feedforward controller is primarily determined by the extent to which it can ca...
Physics-guided neural networks (PGNNs) enable accurate identification of inverse system dynamics by ...
Ever-increasing throughput specifications in semiconductor manufacturing require operating high-prec...
An increasing trend in the use of neural networks in control systems is being observed. The aim of t...
This paper considers model-based feedforward for motion systems. The proposed feedforward controller...
Performance of model–based feedforward controllers is typically limited by the accuracy of the model...
Unknown nonlinear dynamics can limit the performance of model-based feedforward control. The aim of ...
Unknown nonlinear dynamics often limit the tracking performance of feedforward control. The aim of t...
The increasing demand on precision and throughput within high-precision mechatronics industries requ...
The improvements in tracking performance resulting from inversion-based feedforward controllers are ...
The performance of a feedforward controller is primarily determined by the extent to which it can ca...
Advanced feedforward control methods enable mechatronic systems to perform varying motion tasks with...
An artificial feedforward neural network is used for on-line control purposes of a class of single i...
The performance of a feedforward controller is primarily determined by the extent to which it can ca...
Physics-guided neural networks (PGNNs) enable accurate identification of inverse system dynamics by ...
Ever-increasing throughput specifications in semiconductor manufacturing require operating high-prec...
An increasing trend in the use of neural networks in control systems is being observed. The aim of t...
This paper considers model-based feedforward for motion systems. The proposed feedforward controller...
Performance of model–based feedforward controllers is typically limited by the accuracy of the model...