Modeling and compensation of pivot friction in a drive actuator

Author

Goh, H.T. ; Weerasooriya, S. ; Low, T.S. ; Huang, Y.H.

Author_Institution

Magnetics Technol. Center, Nat. Univ. of Singapore, Singapore

Volume

6

fYear

1995

fDate

21-23 Jun 1995

Firstpage

4141

Abstract

With the trend towards smaller form factor disk drives and higher recording densities, frictional effects on the head positioning servo system is receiving increased attention. In this paper, a time-domain stick-slip friction model is proposed for representing the pivot friction. Experimental measurements are made to validate and characterize the model parameters. A discrete-time disturbance observer is incorporated into the conventional state feedback controller to compensate for pivot friction. The track following algorithm is then merged with the proximate time optimal servo (PTOS) algorithm for track seeking. Simulations and analysis are performed in MATLAB and results compared with normal state feedback controllers to show how the proposed control structure can improve friction compensation

Keywords

compensation; discrete time systems; friction; hard discs; observers; position control; servomechanisms; state feedback; time optimal control; discrete-time disturbance observer; drive actuator; friction compensation; frictional effects; head positioning servo system; higher recording densities; pivot friction; proximate time optimal servo; smaller form factor disk drives; state feedback controller; time-domain stick-slip friction model; track following algorithm; track seeking; Actuators; Analytical models; Disk drives; Disk recording; Friction; Magnetic heads; Mathematical model; Servomechanisms; State feedback; Time domain analysis;

fLanguage

English

Publisher

ieee

Conference_Titel

American Control Conference, Proceedings of the 1995

Conference_Location

Seattle, WA

Print_ISBN

0-7803-2445-5

Type

conf

DOI

10.1109/ACC.1995.532711

Filename

532711