RANSDUCER OF DISPLACEMENTS USING PHASE RAIDS OF THE ELECTRIC FIELD OF SURFACE ACOUSTIC WAVES
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Abstract
The method for unambiguous measurement displacements is proposed and theoretically justified. The phase incursion on the surface of the piezoelectric sound-conductor electric field of several surface acoustic waves (SAW) is taken by moving SAW receiver.
The rating of potential metrological parameters of the three-frequency transducer measuring linear displacement in the range of up to 100 mm with the formation of precise, intermediate and rough measurement scales is carried out.
The test results of model of such device, based on piezoelectric sound-conductor of lithium niobate YZ-cut, confirm the possibility of creating highly sensitive displacement transducers. They have a resolution and accuracy properties, that are close to the parameters inductosyns and photoelectric converters based on interferometers, but can be much smaller mass and dimensional indexes, cost and complexity of construction.
Ref. 19, fig. 6
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References
Polyakov, P. F.,Khorunzhj, V. A.,Polyakov, V. P., Akustoelektronika. Fiziko-tekhnolohicheskie osnovy i primenenie. Spravochnoe posobie v 2 t. [Acoustoelectronics. Physical – technological Fundamentals and Application: Handbook: In 2 v.], т. 1, p. P. Polyakov, Ред., Kharkiv: "SMIT company" ltd, 2007, p. 552.
Zhovnir, M. F., Сhernyak, M. G., Chernenko, D. V., Sheremet, L. M., «Vymiriuvalni peretvoriuvachi fizichnikh velychyn nf poherhnevyh akustychnyh khvyliakh [Measuring transducers of surface acoustic wave physical quantities],» Electronics and Communications, т. 16, № 1 (60), pp. 153-157, 2011.
Fachberger, R., Erlacher, A., "Monitoring of the temperature inside a lining of a metallurgical vessel using a SAW temperature sensor," Procedia Chemistry, no. 1 (1), p. 1239 – 1242, 2009. doi: 10.1016/j.proche.2009.07.309.
Bogdan, O., Orlov, A., Petrischev, O., Ulianova, V., "ZnO Nanostrctures as Sensing Element of Acoustic Wave Sensor," Eastern−European Journal of Enterprise Technologies, no. 6/12 (60), p. 16 – 22, 2012. Available at: http://journals.uran.ua/eejet/article/view/6021/5417.
Zbrutsky, A., Chernyak, N., Skripkovsky, G., "Symposium Gyro Technology," in Creation of low cost linear accelerometers for navigation and control systems, Stuttgart (Germany), 2005.
Y. I. Lepykh, «Datchik uhla povorota heneratornoho tipa s elementom na poverkhnostnykh akusticheskikh volnakh [The turn angle gauge of generating type with an element on surface acoustic waves],» Technology and design in electronic equipment, № 3, p. 24 – 25, 2009.
Kalinin, V., Lohr, R., Leigh, A., "2008 IEEE Ultrasonics Symposium," in Development of a calibration procedure for contactless torque and temperature sensors based on SAW resonators, 2008. doi: 10.1109/ultsym.2008.0459
Hribsek, M. F., Tosic, D. V., Radosavljevic, M. R., "Surface Acoustic Wave Sensors in Mechanical Engineering," FME Transactions, no. 38, p. 11 – 18, 2010.
Zhovnir, M. F., Oliinyk, O. O., Pysarenko, L. D., «Matematychni modeli sensoriv peremishchen ta tysku na osnovi zburennia elektrichnihi polia poverkhnevikh akustychnykh khvyl [Mathematical Models of Pressure and Microdisplacement Sensors Based on Electric Field Perturbation of the Surface Acoustic Waves],» Journal of Nano and Electronic Physics, № 8 (1), p. 010241 – 010245, 2016. doi: 10.21272/jnep.8(1).01024
Zhovnir, M. F., Bitov, M. V., Pysarenko, L. D., «Vymiriuvalni peretvoriuvachi mikroperemishchen ta tysku na poverkhnevykh akustychnykh khvyliakh [Measurement tranformers of micromoving and pressure based on the surface acoustic wave],» Electronics and Communications, т. 21, № 4(93), p. 49 – 57, 2016. doi: 10.20535/2312-1807.2016.21.4.81907
M. F. Zhovnir, «Matematychna model pervynnoho peretvoriuvacha liniinykh peremmishchen z rukhomym pryimachem poverkhnevykh akustychnyh khvyl [A mathematical model of the linear displacements primary transducer with a movable surface acoustic waves receiver],» Bulletin of NTU «KhPI». Series: Mechanical – technological systems and complexes, № 7 (1179), p. 48 – 57, 2016.
L. Reindl, "Wireless Passive Sensors: Basic principles and performances," IEEE Sensors, p. 1607 – 1610, 2008. doi: 10.1109/icsens.2008.4716758
Zhovnir, M. F., Kuzmenko, O. M., Pokutnyi, S. I., "Radio SAW-Sensors for Physical Parameters Measurement," Journal of Applied Chemistry, no. 3 (1), p. 7 – 13, 2015.
Mackensen, E., Reindl, L., "Wireless Passive SAW Identification Marks and Sensors," Smart Sensors and MEMS, no. 181, p. 155 – 202, 2004. doi: 10.1007/978-1-4020-2929-5_5.
Matsuzaki, R., Todoroki, A., "Wireless Monitoring of Automobile Tires for Intelligent Tires," MDPI−Sensors, no. 8, p. 8123 – 8138, 2008. doi: 10.3390/s8128123
Chernenko, D., Zhovnir, M., Tsyganok, B., Oliinyk, O., "35th International Spring Seminar on Electronics Technology," in Wireless passive pressure sensor using frequency coded SAW structures, 2012. doi: 10.1109/isse.2012.6273174
D. Morgan, Ustroistva obrabotki sihnalov na poverkhnostnykh akusticheskikh volnakh [Devices for processing signals on surface acoustic waves], Moskow: Radio and communicaion, 1990, p. 416.
Dvornikov, A. A.,Ogurtsov, V. I., Utkin, G.M., stabilie heneratory s filtrami na poverkhnostnykh akusticheskikh volnakh [Stable generators with filters on surface acoustic waves], Moskow: Radio and communication, 1983, p. 136.
Orlov, V. S., Bondarenko, V. S., filtry na poverkhnostnykh akusticheskikkh volnakh [Filters on surface acoustic waves], Moscow: Radio and communication, 1984, p. 272.
