SAW Delay Line for Vibration Sensors

• Authors: J. Filipiak , L. Solarz , G. Steczko
• Languages of publication: EN

Abstracts

EN

The paper presents an analysis of surface acoustic wave delay line. The line consists of two simple interdigital transducers placed on a ST-cut quartz plate. Mid-band operation frequency of the line is 74 MHz. The line will be applied for surface acoustic wave vibration sensor. At the immovable end of the plate there are electric signal feeds to both transducers. This is the cause of increase in signal value going directly between the transducers and the cause of line losses. By means of equivalent electric model of interdigital transducer a loss analysis of the line has been made at 50 Ω load. The analysis allows to minimize line losses by matching the transducers to 50 Ω impedance. This has been practically achieved by a design of transducer geometry and configuration matching 50 Ω impedance, by means of inductance. An analysis of repeated operation characteristics of two interdigital transducers has been made. A signal going directly through capacitance between transducers and signals reflected from the edge of piezoelectric substrate have been presented. Results of theoretical analysis have been compared with experimental examinations.

Keywords

EN

43.25.Fe; 77.65.Dq; 68.35.Iv

Discipline

• 77.65.Dq: Acoustoelectric effects and surface acoustic waves (SAW) in piezoelectrics(see also 43.35.Pt Surface waves in solids and liquids—in Acoustics Appendix; for surface acoustic wave transducers, see 43.38.Rh—in Acoustics Appendix; for acousto-optical effects, see 78.20.hb, and 43.35.Sx—in Acoustics Appendix)
• 68.35.Iv: Acoustical properties

• Publisher: Institute of Physics, Polish Academy of Sciences
• Journal: Acta Physica Polonica A
• Year: 2012
• Volume: 122
• Issue: 5
• Pages: 808-813

Dates

published

2012-11

Contributors

author

J. Filipiak

• Institute of Electronic and Control Systems, Technical University of Częstochowa, Armii Krajowej 17, 02-240 Częstochowa, Poland

author

L. Solarz

• Department of Civil Engineering, Military University of Technology, S. Kaliskiego 2, 00-908 Warsaw, Poland

author

G. Steczko

• Institute of Electronic and Control Systems, Technical University of Częstochowa, Armii Krajowej 17, 02-240 Częstochowa, Poland

References

• [1] H. Wohltjen, R. Dessy, Anal. Chem. 51, 1458 (1979)
• [2] E. Gizeli, M. Liley, C.R. Love, H. Vogel, Anal. Chem. 69, 4808 (1997)
• [3] C. Tyszkiewicz, T. Pustelny, Opt. Appl. 34, 507 (2004)
• [4] P. Struk, T. Pustelny, K. Gut, K. Golaszewska, E. Kaminska, M. Ekielski, I. Pasternak, E. Łusakowska, A. Piotrowska, Acta Phys. Pol. A 116, 414 (2009)
• [5] J. Filipiak, L. Solarz, G. Steczko, Acta Phys. Pol. A 120, 598 (2011)
• [6] L.D. Clayton, E.F. EerNisse, IEEE Trans. Ultrason. Ferroelectr. Freq. Control 45, 1196 (1998)
• [7] Q. Jiang, X.M. Yang, H.G. Zhou, J.S. Yang, Sensors Actuators A 118, 3 (2005)
• [8] B. Drafts, Sensors 10, 1 (2000)
• [9] E. Hauden, Arch. Acoust. 16, 47 (1991)
• [10] J. Filipiak, L. Solarz, G. Steczko, Mol. Quant. Acoust. 28, 71 (2007)
• [11] J. Filipiak, Surface Acoustic Wave Acceleration Sensors, Politechnika Częstochowska, Częstochowa 2006, p. 121 (in Polish)
• [12] J. Filipiak, C. Kopycki, Sensors Actuators 76, 318 (1999)
• [13] J. Filipiak, L. Solarz, G. Steczko, Acta Phys. Pol. A 116, 302 (2009)
• [14] J. Filipiak, L. Solarz, G. Steczko, Acta Phys. Pol. A 120, 593 (2011)
• [15] L. Matthews, Surface Wave Filters, Wiley, New York 1997
• [16] P. Morgan, Surface Wave Devices for Signal Processing, Elsevier, London 1985
• [17] A. Oliner, Acoustic Surface Waves, Springer Verlag, Berlin 1978
• [18] J. Filipiak, L. Solarz, G. Steczko, Przegląd Elektrotechniczny 11a, 177 (2010) (in Polish)

Identifiers

DOI

10.12693/APhysPolA.122.808