INTEGRATED AND OBJECT-ORIENTED MECHATRONIC MODELLING OF PIEZOELECTRIC TRANSDUCERS USING LINEAR GRAPHS

Morteza Ganji, Saeed Behbahani, and Clarence W. de Silva

References

  1. [1] C.W. de Silva, Mechatronics: A foundation course (BocaRaton, FL: Taylor & Francis, CRC Press, 2010).
  2. [2] D. Rowell and D.N. Wormley, System dynamics, an introduc-tion (Upper Saddle River, NJ: Prentice-Hall, 1997).23
  3. [3] C.W. de Silva, Modeling and control of engineering systems(Boca Raton, FL: Taylor & Francis, CRC Press, 2009).
  4. [4] V. Kutiˇs, MEMS piezoelectric pressure sensor – modeling andsimulation, Procedia Engineering, 48, 2012, 338–345.
  5. [5] B. Baylan, U. Aridogan, and C. Basdogan, Finite elementmodeling of a vibrating touch screen actuated by piezo patchesfor haptic feedback, Haptics: Perception, Devices, Mobility,and Communication, Lecture Notes in Computer Science, 7282,2012, 47–57.
  6. [6] J.J. Granda, The role of bond graph modeling and simulation inmechatronics systems, Mechatronics, 12(9), 2002, 1271–1295.
  7. [7] O. Kursua, A. Kruusingb, M. Pudasb, and T. Rahkonena,Piezoelectric bimorph charge mode force sensor, Sensors andActuators A: Physical, 153(1), 2009, 42–49.
  8. [8] M. Reichert and H. Murrenhoff, New concepts and design ofhigh response hydraulic valves using piezo-technology, PowerTransmission and Motion Control, RWTH Aachen University,Germany, 2006, 401–414.
  9. [9] Sh. Lin and H. Tian, Study on the sandwich piezoelectricceramic ultrasonic transducer in thickness vibration, SmartMaterials Structures, 17(1), 2008, 1–9.
  10. [10] L. Lonini, D. Accoto, S. Petron, and E. Guglielmelli, Dispensingan enzyme-conjugated solution into an ELISA plate by adapt-ing ink-jet printers, Journal of Biochemical and BiophysicalMethods, 70(6), 2008, 1180–1184.
  11. [11] C. Belly and W. Charon, Benefits of amplification in an inertialstepping motor, Mechatronics, 22(2), 2012, 177–183.
  12. [12] Y. Soeno, S. Ichikawa, T. Tsuna, Y. Sato, and I. Sato,Piezoelectric piggy-back micro-actuator for hard disk drive,IEEE Transactions on Magnetics, 35(2), 1999, 983–987.
  13. [13] I. Kuehne, D. Marinkovic, G. Eckstein, and H. Seidel, A newapproach for MEMS power generation based on a piezoelectricdiaphragm, Sensors and Actuators A: Physical, 142(1), 2008,292–297.
  14. [14] J.L. Donald, Engineering analysis of smart material systems(Hoboken, New Jersey: John Wiley & Sons, 2007).
  15. [15] O. Gomis-Bellmunt, F. Ikhouane, P. Castell-Vilanova, and J.Bergas-Jan, Modeling and validation of a piezoelectric actuator,Electrical Engineering, 89(8), 2007, 629–638.
  16. [16] Y. Pasco and A. Berry, Consideration of piezoceramic actuatornonlinearity in the active isolation of deterministic vibration,Journal of Sound and Vibration, 289(3), 2006, 481–508.
  17. [17] R.C. Smith, A.G. Hatch, B. Mukherjee, and S. Liu, A homog-enized energy model for hysteresis in ferroelectric materials:General density formulation, Journal of Intelligent MaterialSystems and Structures, 16(4), 2005, 713–732.
  18. [18] J.M. Rodriguez-Fortun, J. Orus, F. Buil, and J.A. Castellanos,General bond graph model for piezoelectric actuators andmethodology for experimental identification, Mechatronics,20(2), 2010, 303–314.
  19. [19] I. Schwartz, Smart materials (Boca Raton, FL: Taylor &Francis, CRC Press, 2008).
  20. [20] J.J. Dosch, D.J. Inman, and E. Garcia, A self-sensing piezoe-ictric actuator for collocated control, Journal of IntelligentMaterial Systems and Structures, 3(1), 1992, 165–185.

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