Abstract :
This article focuses on the design and control of nanopo-sitioning systems (nanoposi-tioners) that operate mostly in a repetitive fashion. In addition to accuracy, speed is also a crucial requirement for these systems. Multi-axis nanopositioners are critical in applications such as atomic force microscopy (AFM) [1], fiber optic alignment [2], micro- and nanoma-chining [3], [4], and nanometrology [5], [6]. More specifically, for video-rate scanning probe microscopy (SPM) and high-throughput probe-based nano-fabrication [7], the desired motion trajectory of the nanopositioner repeats from one operating cycle to the next and the motion should be as fast and accurate as possible. However, vibrations caused by mechanical resonance are a major factor limiting the speed. Typically, the bandwidth of these systems is limited by the first mode of vibration [8], [9].
Keywords :
atomic force microscopy; design engineering; micromachining; motion control; nanofabrication; nanopositioning; periodic control; vibration control; AFM; SPM; atomic force microscopy; fiber optic alignment; high-speed nanopositioning control; high-speed nanopositioning design; high-throughput probe-based nanofabrication; mechanical resonance; micromachining; multiaxis nanopositioners; nanomachining; nanometrology; repetitive control; serial-kinematic nanopositioners; video-rate scanning probe microscopy; Atomic force microscopy; Dynamics; Hysteresis; Nanopositioning; Piezoelectric actuators; Scanning probe microscopy;
