Abstract
The next-generation semiconductor lithography equipment needs a suitable actuator to meet the requirement of high-speed, high-acceleration and high-precision. Reluctance actuator, which has a unique property of small volume, low current and can produce great force, is a very suitable choice. One of the major application challenges of reluctance actuator is the hysteresis of the force, which has a nonlinear relationship with respect to the current and is directly related to the final accuracy in the nanometer range. Therefore, it is necessary to study the control method for the hysteresis in reluctance force. This paper proposes a hysteresis control configuration for the current-driven variable reluctance actuator with hysteresis using the adaptive multilayer neural network (MNN), which is used as a learning machine of hysteresis. The simulation results show that the proposed method is effective in overcoming the hysteresis.
Publisher
Trans Tech Publications, Ltd.
Reference11 articles.
1. C. Grant, High-Resolution Patterning: A View of the Future, Plenary Presentation in Conference of Advanced Lithography, San Jose, California, USA, (2012).
2. Hans Butler, Position Control in Lithographic Equipment, IEEE Control System Magazine, Vol. 31. pp.28-47, (2011).
3. Vrijsen NH, Jansen JW, Lomonova EA. Comparison of linear voice coil and reluctance actuators for high-precision applications. In: 14th International power electronics and motion control conference (EPE/PEMC), (2010).
4. A. Katalenic, C.M.M. van Lierop and P.P.J. van den Bosch, Smooth parametric hysteresis operator for control, IFAC 18th World Congress, Milano (2011).
5. Vrijsen, N.H., Jansen, J.W. and Lomonova, E.A. Force prediction including hysteresis effects in a short-stroke reluctance actuator using a 3d-FEM and the Preisach model. Applied Mechanics and Materials, 416-417, 187-194, (2013).
Cited by
2 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献