Sage Journals: Discover world-class research

Abstract

The present work investigates the adverse effects of non-collocated sensors and actuators on the phase characteristics of flexible structures and the ensuing implications on the performance of structural controllers. Two closed-loop systems are considered. The first one consists of a pinned-free flexible beam with the control torque applied at the pinned-end. The second one is a clamped-free deformable beam with the control moment generated by two piezoelectric actuators bonded at the top and bottom surfaces near the clamped-end. The phase angle contours for both systems were generated as functions of the normalized sensor location and the excitation frequency. They illustrate the loci of the imaginary open-loop zeros along with the resulting minimum and non-minimum phase regions of the systems as the sensors sweep the entire span of the beams. Two structural controllers are designed based on the sliding mode methodology and the active damping control strategy to attenuate the undesired in-plane transverse deformation of the pinned-free beam. The results have revealed three distinct regions for the sensor’s location whereby the performance of the sliding mode controller can be stable, unstable, or stable after incorporating a remedial action into the control algorithm based on the phase angle contour information of the open-loop system. On the other hand, the active damping controller eliminated the overall in-plane transverse deformation by both active damping and having the first two elastic modes being equal in magnitude and opposite in sign. The dissipative nature of this controller and the dependency of its gains on the mode shapes of the beam have yielded a robust and stable performance of the closed-loop system irrespective of the sensor location.

Keywords

Active damping control non-collocated sensors and actuators non-minimum phase systems phase angle contour sliding mode control structural controllers

Get full access to this article

View all access options for this article.

References

Bazzi

Chalhoub

(2005) Fuzzy-sliding mode controller for a flexible single-link robotic manipulator. Journal of Vibration and Control 11(2): 295–314.

Book

Maizza-Neto

Whitney

(1975) Feedback control of two beams, two joint systems with distributed flexibility. ASME Journal of Dynamic Systems, Measurement and Control 97(4): 424–431.

Cannon

RH Rosenthal

(1984) Experiments in control of flexible structures with noncolLocated sensors and actuators. Journal of Guidance, Control, and Dynamics 7(5): 546–553.

Cannon

Schmitz

(1984) Initial experiments on the end-point control of a flexible one-link robot. International Journal of Robotics Research 3(3): 62–75.

Chalhoub

Zhang

(1993) Reduction of the end effector sensitivity to the structural deflections of a single flexible link: theoretical and experimental results. ASME Journal of Dynamic Systems, Measurement and Control 115(4): 658–666.

Chen

Chalhoub

(1997) Modeling and control of transverse and torsional vibrations in a spherical robotic manipulator: theoretical and experimental results. ASME Journal of Dynamic Systems, Measurement and Control 119(3): 421–430.

Chodavarapu PA and Spong MW (1996) On noncollocated control of a single flexible link. In: IEEE International Conference on Robotics and Automation Minneapolis, Minnesota, 22--28 April, vol. 2, pp. 1101–1106.

Choi

Cheong

Shin

(1995) Sliding mode control of vibration in a single-link flexible arm with parameter variations. Journal of Sound and Vibration 179(5): 737–748.

Crawley

De Luis

(1987) Use of piezoelectric actuators as elements of intelligent structures. American Institute of Aeronautics and Astronautics Journal 25(10): 1373–1385.

10.

Fleming FM and Crawley EF (1991) The zeroes of controlled structures: sensor/actuator attributes and structural modeling. In: Proceedings of the 31th Structures, Structural Dynamics, and Materials Conference, Baltimore, Maryland, vol. 1, pp. 1806–1816.

11.

Forbes

Damaren

(2012) Single-link flexible manipulator control accommodating passivity violations: theory and experiments. IEEE Transactions on Control Systems Technology 20(3): 652–662.

12.

Freudenberg

Looze

(1985) Right half plane poles and zeros and design tradeoffs in feedback systems. IEEE Transactions on Automatic Control AC-30(6): 555–565.

13.

Fuller

Elliott

Nelson

(1996) Active Control of Vibration, CA: Academic Press.

14.

Gevarter

(1970) Basic relations of flexible vehicles. AIAA Journal 8(4): 666–672.

15.

Khalil

(1996) Nonlinear Systems, 2nd edn. Englewood Cliffs, NJ: Prentice Hall.

16.

Kim

Inman

(2001) Reduction of observation spillover in vibration suppression using a sliding mode observer. Journal of Vibration and Control 7(7): 1087–1105.

17.

Wang

(2011) An intelligent sliding mode controller for vibration suppression in flexible structures. Journal of Vibration and Control 17(14): 2187–2198.

18.

Mamani

Becedas

Feliu

(2012) Sliding mode tracking control of a very lightweight single-link flexible robot robust to payload changes and motor friction. Journal of Vibration and Control 18(8): 1141–1155.

19.

Meirovitch

(1967) Analytical Methods in Vibrations, New York: Macmillan.

20.

Meirovitch

(1975) Elements of Vibrations Analysis, New York: McGraw-Hill.

21.

Park JH and Asada H (1990a) Design and analysis of flexible arms for minimum-phase endpoint control. In: Proceedings of the American Control Conference. San Diego, California, 23–25 May, vol. 1, pp. 1220–1225.

22.

Park JH and Asada H (1990b) Design and control of minimum-phase flexible arms with torque transmission mechanisms. In: Proceedings of the IEEE International Conference on Robotics and Automation. Cincinnati, Ohio, 13--18 May, vol. 3, pp. 1790–1795.

23.

Pota HR and Vidyasagar M (1991) Passivity of flexible beam transfer functions with modified outputs. In: Proceedings of the 1991 IEEE International Conference on Robotics and Automation, Sacramento, California, 9--11 April, vol. 3, pp. 2826–2831.

24.

Preumont

(2011) Vibration Control of Active Structures: An Introduction (Vol. 179). Berlin: Springer.

25.

Rahman

Mat Isa

Ali

Anuar

(2013) Control of flexible beam with unmodelled dynamics using second-order pole placement and LQR techniques. Applied Mechanics and Materials 393: 675–682.

26.

Shao

Chen

(2013) Active vibration control in cantilever-like structure: a time delay compensation approach. Journal of Vibration and Control 19(5): 674–685.

27.

Slotine

JJE

(1991) Applied Nonlinear Control, Englewood Cliffs, NJ: Prentice Hall.

28.

Song

(2007) Active vibration suppression of a smart flexible beam using a sliding mode based controller. Journal of Vibration and Control 13(8): 1095–1107.

29.

Spector

Flashner

(1990) Modeling and design implications of noncollocated control in flexible systems. ASME Journal of Dynamic Systems, Measurement, and Control 112(2): 186–193.

30.

Vakil

Fotouhi

Nikiforuk

(2011) Trajectory tracking for the end-effector of a class of flexible link manipulators. Journal of Vibration and Control 17(1): 55–68.

31.

Wang D and Vidyasagar M (1989) Transfer functions for a single flexible link. In: Proceedings of IEEE International Conference on Robotics and Automation. Scottsdale, Arizona, 14--19 May, pp. 1042–1047.

32.

Williams T (1990) Model order effects on the transmission zeros of flexible space structures. In: Proceedings of the American Control Conference. San Diego, California, 23--25 May, vol. 1, pp. 876–877.

33.

Yang

(1997) Stability analysis of linear structural control systems with noncolocated feedback. Computers & Structures 62(4): 685–690.

34.

Yang

Lee

(1994) Modal analysis of stepped beams with piezoelectric materials. Journal of Sound and Vibration 176(3): 289–300.

35.

Yang

Mote

Jr. (1991) Stability of non-conservative linear discrete gyroscopic systems. Journal of Sound and Vibration 147(3): 453–464.

36.

Young D and Felgar RP (1949) Tables of Characteristic Functions Representing Normal Modes of Vibration of a Beam. Texas: University of Texas, Publication 4913.

37.

Zhang

Scorletti

Ichchou

Mieyeville

(2013) Phase and gain control policies for robust active vibration control of flexible structures. Smart Materials and Structures 22(7): 075025.

Enhanced structural controllers for non-collocated systems

Abstract

Keywords

Get full access to this article

References