In the manual control of a dynamic system, the human controller (HC) often follows a visible and predictable reference path. Compared with a purely feedback control strategy, performance can be improved by making use of this knowledge of the reference. The operator could effectively introduce feedforward control in conjunction with a feedback path to compensate for errors, as hypothesized in literature. However, feedforward behavior has never been identified from experimental data, nor have the hypothesized models been validated. This paper investigates human control behavior in pursuit tracking of a predictable reference signal while being perturbed by a quasi-random multisine disturbance signal. An experiment was done in which the relativ...
Improved understanding of human adaptation can be used to design better (semi-)automated systems tha...
Mathematical control models are widely used in tuning manual control systems and understanding human...
Human modelling approaches are typically limited to feedback-only, compensatory tracking tasks. Adva...
In the manual control of a dynamic system, the human controller (HC) often follows a visible and pre...
The human in manual control of a dynamical system can use both feedback and feedforward control stra...
The human controller (HC) in manual control of a dynamical system often follows a visible and predic...
Realistic manual control tasks typically involve predictable target signals and random disturbances....
Understanding how humans control a vehicle (cars, aircraft, bicycles, etc.) enables engineers to des...
This paper investigates the modeling of humanmanual control behavior for pursuit tracking tasks in w...
Mathematical human control models are widely used in tuning manual control systems and understanding...
In the manual control of a dynamic system, the human controller (HC) is often required to follow a v...
The human controller (HC) can greatly improve target-tracking performance by utilizing a feedforward...
The 1960s crossover model is widely applied to quantitatively predict a human controller's (HC's) ma...
Mathematical control models are widely used in tuning manual control systems and understanding human...
Improved understanding of human adaptation can be used to design better (semi-)automated systems tha...
Mathematical control models are widely used in tuning manual control systems and understanding human...
Human modelling approaches are typically limited to feedback-only, compensatory tracking tasks. Adva...
In the manual control of a dynamic system, the human controller (HC) often follows a visible and pre...
The human in manual control of a dynamical system can use both feedback and feedforward control stra...
The human controller (HC) in manual control of a dynamical system often follows a visible and predic...
Realistic manual control tasks typically involve predictable target signals and random disturbances....
Understanding how humans control a vehicle (cars, aircraft, bicycles, etc.) enables engineers to des...
This paper investigates the modeling of humanmanual control behavior for pursuit tracking tasks in w...
Mathematical human control models are widely used in tuning manual control systems and understanding...
In the manual control of a dynamic system, the human controller (HC) is often required to follow a v...
The human controller (HC) can greatly improve target-tracking performance by utilizing a feedforward...
The 1960s crossover model is widely applied to quantitatively predict a human controller's (HC's) ma...
Mathematical control models are widely used in tuning manual control systems and understanding human...
Improved understanding of human adaptation can be used to design better (semi-)automated systems tha...
Mathematical control models are widely used in tuning manual control systems and understanding human...
Human modelling approaches are typically limited to feedback-only, compensatory tracking tasks. Adva...