This article studies ultra-high-precision positioning with piezoactuators and illustrates the results with an example Scanning Probe Microscopy (SPM) application. Loss of positioning precision in piezoactuators occurs (1) due to hysteresis during long range applications, (2) due to creep effects when positioning is needed over extended periods of time, and (3) due to induced vibrations during high-speed positioning. This loss in precision restricts the use of piezoactuators in high-speed positioning applications like SPM-based nanofabrication, and ultra-high-precision optical systems. An integrated inversion-based approach is presented in this article to compensate for all three adverse affects—creep, hysteresis, and vibrations. The method is applied to an Atomic Force Microscope (AFM) and experimental results are presented that demonstrate substantial improvements in positioning precision and operating speed.

Issue Section:
Technical Papers
Keywords:
atomic force microscopy, piezoelectric actuators, creep, compensation, micropositioning, elastic hysteresis, vibration control
Topics:
Atomic force microscopy, Creep, Modeling, Vibration, Dynamics (Mechanics), Scanning probe microscopy
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Copyright © 2001
 by ASME
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