Research on Robust Control of Micromachined Accelerometers

Wu, Wei-ming

22 August 2000

This paper presents the research on the robust control of micromachined accelerometers. First, we present different micromaching techniques and compare, analyze the accelerometers with different methods of signal pick-off. Besides the different methods of signal pick-off(the position detection of the seismic mass) and structure designs, we can enhance the performance such as stability, bandwidth, sensitivity, resolution and dynamic range etc. by suitable feedback controllers. So inside the front part of the paper are the analyses for the controllers of different types of accelerometers so far. Moreover, we design the controllers by robust control in different methods with the model of one specific type of micromachined tunneling accelerometer. Because of the robust controllers, the accelerometers can be stable and have good performance under different environments and uncertainties. At last we analyze and compare the controllers designed by -synthesis and gap metric.

mu synthesis

accelerometer

robust control

gap metric

An H-infinite Based Sensitivity Function Shaping Method

Huang, Yan-Chuen

24 July 2002

Abstract This thesis presents that the closed-loop sensitivity function shaping combined with -synthesis applies to design the controller with structured uncertainties. The sensitivity function shaping is directly based on the indices of the closed-loop performances. The closed-loop frequency response and the robust stability for the system could approach the designed performances by adjusting weighting functions. Since the robust performance of the closed-loop systems bases on the index of the open-loop function in the loop shaping, it may not accomplish the requirement of the designer. The loop shaping can¡¦t be applied to design controllers for the system with structured uncertainties. Therefore, using the closed-loop sensitivity function shaping to design controller will contain the system with structured uncertainties and satisfy the closed-loop performance.

Mu-synthesis

Loop Shaping

Sensitivity Function Shaping

Development of Chatter Attenuation Robust Control for an AMB Machining Spindle

Pesch, Alexander Hans

January 2013

No description available.

Mechanical Engineering

Engineering

Machining Chatter

Active Magnetic Bearing

Robust Control

mu-synthesis

AMB

Missile autopilot design using Mu-Synthesis

Bibel, John Eugene

25 August 2008

Due to increasingly difficult threats, current air defense missile systems are pushed to the limits of their performance capabilities. In order to defend against these more stressing threats, interceptor missiles require greater maneuverability, faster response time, and increased robustness to more severe environmental conditions. One of the most critical missile system elements is the flight control system, since its time constant is typically half of the total missile system time constant. Conventional autopilot design techniques have worked well in the past, but in order to satisfy future and more stringent design specifications, new design methods are necessary. Robust control techniques (in particular, H-Infinity Control and Mu-Synthesis) and their application to the design of missile autopilots are addressed in this thesis. In addition, conventional autopilot designs are performed as comparative benchmarks. This paper reviews the missile autopilot design problem and presents descriptions of the classical and H-Infinity/Mu design methods. Missile autopilot designs considering both rigid-body dynamics and elastic-body dynamics are presented. Comparisons of the design approaches and results are also discussed. The results show that the application of robust control techniques to the design of missile autopilots can improve the performance and stability robustness characteristics of the flight control system. / Master of Science

missile autopilot

structured singular value

H-Infinity control

Mu-Synthesis

LD5655.V855 1998.B534

Model Identification, Updating, and Validation of an Active Magnetic Bearing High-Speed Machining Spindle for Precision Machining Operation

Wroblewski, Adam C.

13 October 2011

No description available.

Electromagnetism

Engineering

Industrial Engineering

Mechanical Engineering

rotordynamics

modeling

spindle

high speed

active magnetic bearing

AMB

machining

high speed machining

system identification

open loop model

model updating

optimization

robust control

mu-synthesis

mu-control