Method for controlling an actuator

The invention claimed is: 1. A method of controlling a pneumatic actuator for actuation of a pneumatically actuated device, the actuator comprising a piston and a pneumatic cylinder, the piston being arranged to move axially in the pneumatic cylinder, the piston moving as a function of a pressure in a pressure chamber of the pneumatic cylinder, the method comprising the steps of: determining, via a path sensor, a present position and movement of the piston within the pneumatic cylinder to a desired position; determining at least one pilot control component comprising an amount of force required to move the piston within the pneumatic cylinder from the present position to the desired position, with the at least one pilot control component being determined as a function of at least one of a first sliding friction force and a first static friction force of the piston moving within the pneumatic actuator cylinder from the present position to the desired position; and adjusting the pressure in the pressure chamber, as a function of the at least one pilot control component, via a control unit which controls at least one of a valve, a pressure regulating means, and a pressure generating device; wherein at least one of the first sliding friction force and the first static friction force are position dependent forces that need to be overcome by the pressure in the pressure chamber for moving the piston in the pneumatic cylinder, and the first sliding friction force and the first static friction force are dependent on a movement direction of the piston and the present position of the piston within the pneumatic cylinder. 2. The method according to claim 1 , further comprising selecting the at least one pilot control component based on a difference between the first sliding friction force and the first static friction force such that, if the piston is to be moved from rest in a defined movement direction which is the same as a previous movement direction of the piston, the piston is able to overcome a difference between the first sliding friction force acting in the defined movement direction and the first static friction force acting in the defined movement direction. 3. The method according to claim 1 , further comprising selecting the at least one pilot control component based on the first sliding friction force, a second sliding friction force in a direction opposite to the first sliding friction force, and the first static friction force such that, if the piston is to be moved from rest in a defined movement direction which is opposite to a previous movement direction of the piston, the piston is able to overcome a difference between the first sliding friction force acting in the defined movement direction and the first static friction force acting in the defined movement direction, and a difference between the first and the second sliding friction forces acting in the defined movement direction and in a direction opposite to the defined movement direction. 4. The method according to claim 1 , further comprising selecting the at least one pilot control component such that, if the piston is at rest and a subsequent movement direction of the piston is unknown, the at least one pilot control component corresponds to one half of a difference between the first static friction force and a second static friction force acting in direction opposite to the first static friction force.