Iterative feedback tuning (IFT) enables the tuning of feedback controllers based on measured data without the need for a parametric model. The aim of this paper is to develop an efficient method for MIMO IFT that reduces the required number of experiments. Using a randomization technique, an unbiased gradient estimate is obtained from a single dedicated experiment, regardless of the size of the MIMO system. This gradient estimate is employed in a stochastic gradient descent algorithm. Simulation examples illustrate that the approach reduces the number of experiments required to converge
A new iterative feedback/feed-forward tuning (IFFT) method is presented for multiple-input multiple-...
A new ’model-free’ iterative controller tuning method is presented for multiple-inputmultiple output...
Learning can substantially increase the performance of control systems that perform repeating tasks....
Learning can substantially increase the performance of control systems that perform repeating tasks....
Parameterized feedforward control is at the basis of many successful control applications with varyi...
In this contribution, we extend the Iterative Feedback Tuning (IFT) control method of [3, 4] to a mu...
Despite the vast amount of delivered theoretical results, regarding the topic of controller design, ...
Iterative Feedback Tuning (IFT) is a data-based method for the iterative tuning of restricted comple...
Optimal performance of process control requires a controller synthesis based on a perfor-mance crite...
Data-driven iterative learning control can achieve high performance for systems performing repeating...
Iterative feedback tuning (IFT) enables the data-driven tuning of controller parameters without the ...
International audienceIterative feedback tuning (IFT) is a data-based method for the iterative tunin...
Data-driven iterative learning control can achieve high performance for systems performing repeating...
Iterative feedback tuning (IFT) is a data-based method for the optimal tuning of a low order control...
Feedforward control with task flexibility for MIMO systems is essential to meet ever-increasing dema...
A new iterative feedback/feed-forward tuning (IFFT) method is presented for multiple-input multiple-...
A new ’model-free’ iterative controller tuning method is presented for multiple-inputmultiple output...
Learning can substantially increase the performance of control systems that perform repeating tasks....
Learning can substantially increase the performance of control systems that perform repeating tasks....
Parameterized feedforward control is at the basis of many successful control applications with varyi...
In this contribution, we extend the Iterative Feedback Tuning (IFT) control method of [3, 4] to a mu...
Despite the vast amount of delivered theoretical results, regarding the topic of controller design, ...
Iterative Feedback Tuning (IFT) is a data-based method for the iterative tuning of restricted comple...
Optimal performance of process control requires a controller synthesis based on a perfor-mance crite...
Data-driven iterative learning control can achieve high performance for systems performing repeating...
Iterative feedback tuning (IFT) enables the data-driven tuning of controller parameters without the ...
International audienceIterative feedback tuning (IFT) is a data-based method for the iterative tunin...
Data-driven iterative learning control can achieve high performance for systems performing repeating...
Iterative feedback tuning (IFT) is a data-based method for the optimal tuning of a low order control...
Feedforward control with task flexibility for MIMO systems is essential to meet ever-increasing dema...
A new iterative feedback/feed-forward tuning (IFFT) method is presented for multiple-input multiple-...
A new ’model-free’ iterative controller tuning method is presented for multiple-inputmultiple output...
Learning can substantially increase the performance of control systems that perform repeating tasks....