Precision Motion Control

 

Precision motion is an indispensable part of microelectronic systems and their manufacturing, for example, read/write head motion in disk drives, chip placement motion in surface mount machines, laser drill motion in electronic packaging, scanning motion in confocal microscope, etc.  Precision motion is also critical for micro-assembly and Micro-Electro-Mechanical-Systems (MEMS) actuation in applications to RF, micro-optic and micro-fluidic devices.  With the continuing demand on high performance and low cost, the requirement on the motion subsystem, in terms of speed and precision, is also ever more stringent.  Due to the high volume of data or parts these systems have to process, even a few percentage of throughput increase can have major economic impacts in terms of the overall system performance improvement and production cost saving.

 

A key impediment to performance improvement is the inherent flexible dynamics in such systems.  This is especially true in high precision applications where even minute vibration in seemingly stiff structures can compromise the motion requirement.  In addition, the flexible dynamics frequently vary from one machine to another, making their incorporation into the control design difficult.  Other major challenges to the control system design include friction (with its inherent hysteretic behavior), actuator saturation, and noise.

 

A tight feedback control loop can achieve good nominal response and noise and disturbance rejection, but the performance is limited by model uncertainty and noise.  Feedforward compensation is typically applied to achieve additional performance gain.  Many feedforward control schemes have been proposed, including time optimal control, inverse dynamics, finite impulse response filter, and output matching. However, a design methodology that can achieve fast settling time in the presence of nonlinearity, flexible dynamics, inequality constraints, and model uncertainty remains elusive.  In the case of MEMS actuators, these factors become even more difficult to address due to the absence of adequate position feedback sensors in many applications.

 

We have worked with a leading electronics packaging machine manufacturer for several years addressing the precision motion problems faced by its machines.  The challenges are: tight performance requirement in terms of settling band and settling time, large motion range relative to the settling band, output velocity and acceleration saturation constraints, friction and hysteresis nonlinearity, and variation of the resonant dynamics from machine to machine.  We have developed new identification, iterative learning, and on-line adaptive control techniques that significantly improve what could be currently achieved.  These algorithms have been incorporated into the company’s latest products. We are currently focusing on the friction modeling and compensation, as well as motion planning (similar to the so-called motorized traveling salesman problem – but for ½ million – 1 million points!).

 

Laboratory Setup

       

 

Application (electronic packaging)

 

 

Scanning Optical Mosaic Scope (SOMS)

 

A related effort involves the design of a large-field-of-view optical microscope using scanning mirrors.  The motion control of the scanning mirror also draws on our research in precision motion control.

 

Current Prototype

 

 

Sample Cell Images

Publications:

• D.O. Popa, B.H. Kang, J.T.Wen, H.E. Stephanou, G. Skidmore, A. Geisberger, "Dynamic Modeling and Open-Loop Control Of Thermal Bimorph MEMS Actuators," 2003 IEEE Conference on Robotics and Automation, Taipei, Taiwan, Sept, 2003.
• B. Potsaid, Y. Bellouard, J.T. Wen, "Scanning Optical Mosaic Scope for Dynamic Biological Observations and Manipulation," Intelligent Robotics Systems (IRoS), Las Vegas, NV, Oct., 2003. (invited talk)
• J.T. Wen, B. Potsaid, "An Experimental Study of a High Performance Motion Control System," American Control Conference, Boston, June 30-July 2, 2004.
• B. Potsaid, J.T. Wen, "High Performance Motion Tracking Control," Conference on Control Applications, Taipei, Taiwan, Aug. 31-Sept. 2, 2004.   (Best Student Paper Award)

Experimental Result (video) 

Videos taken with our scanning optical mosaic scope (SOMS)

o        cell division

o        gripper motion

 

Acknowledgment
This material is based upon work supported by the National Science Foundation under Grant No. CMS-0301827.  Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the National Science Foundation.  This work is also supported in part by the Center for Automation Technologies (CAT) under a block grant from the New York State Office of Science, Technology, and Academic Research (NYSTAR).

Contact Information:

John T. Wen
Office: CII 8213
Voice: (518)-276-8744
Fax: (518)-276-4897
Email: wen@cat.rpi.edu