This paper describes the open-loop and closed-loop control for quasi-static microscanners exploiting the inherent flatness property. The developed nonlinear control method is verified on a gimbaled quasi-static/resonant scanning micro mirror with electrostatic staggered vertical comb (SVC) drive actuation. Based on a mechatronic micro mirror model, we present a flatness-based feed forward control method using jerk-limited trajectories to reduce undesired oscillations. For the closed-loop control we introduce a stabilizing linearizing feedback including an extended Luenberger observer for improvement of the command tracking in presence of model inaccuracies. The experimental results for both scenarios, open-loop and closed-loop control, are ...
This paper presents a control algorithm for a micro-electro-mechanical system (MEMS) fast steering m...
We present a 2D MEMS raster scanning micromirror based on a novel actuation concept for the (quasi-)...
In this paper we present a novel approach to achieve indirect quasistatic deflection of 2D MEMS scan...
This paper describes a nonlinear command tracking scheme for an electrostatic laser scanning micromi...
This paper describes open loop control measures for performance improvements of electrostatic microm...
In this paper we present a 2D raster scanning quasi-static/resonant micro mirror being controlled in...
Current works at the Fraunhofer Institute for Photonic Microsystems (FhG-IPMS) are focusing on the d...
This paper describes an open loop control approach with analog impedance feedback damping for quasis...
In this paper we present closed-loop control for accurate positioning of micro optical mechanical sy...
Command shaping is a driving technique for handling the large settling time of the high-Q-MEMS actua...
Microelectromechanical Systems (MEMS) technology has already led to advances in optical imaging, sca...
The quasi-static operations of MEMS mirror are very sensitive to undesired oscillations due to its v...
International audienceTypical adaptive optics (AO) applications require continual measurement and co...
This paper describes an input shaping method based on an experimental transfer function to effective...
[[abstract]]We demonstrate a closed-loop adaptive control scheme for achieving accurate positioning ...
This paper presents a control algorithm for a micro-electro-mechanical system (MEMS) fast steering m...
We present a 2D MEMS raster scanning micromirror based on a novel actuation concept for the (quasi-)...
In this paper we present a novel approach to achieve indirect quasistatic deflection of 2D MEMS scan...
This paper describes a nonlinear command tracking scheme for an electrostatic laser scanning micromi...
This paper describes open loop control measures for performance improvements of electrostatic microm...
In this paper we present a 2D raster scanning quasi-static/resonant micro mirror being controlled in...
Current works at the Fraunhofer Institute for Photonic Microsystems (FhG-IPMS) are focusing on the d...
This paper describes an open loop control approach with analog impedance feedback damping for quasis...
In this paper we present closed-loop control for accurate positioning of micro optical mechanical sy...
Command shaping is a driving technique for handling the large settling time of the high-Q-MEMS actua...
Microelectromechanical Systems (MEMS) technology has already led to advances in optical imaging, sca...
The quasi-static operations of MEMS mirror are very sensitive to undesired oscillations due to its v...
International audienceTypical adaptive optics (AO) applications require continual measurement and co...
This paper describes an input shaping method based on an experimental transfer function to effective...
[[abstract]]We demonstrate a closed-loop adaptive control scheme for achieving accurate positioning ...
This paper presents a control algorithm for a micro-electro-mechanical system (MEMS) fast steering m...
We present a 2D MEMS raster scanning micromirror based on a novel actuation concept for the (quasi-)...
In this paper we present a novel approach to achieve indirect quasistatic deflection of 2D MEMS scan...