Modified microacoustomechanical noise-immune gyroscope

The work objective is to develop a new modified microacoustomechanical noise-immune gyroscope. It allows converting the angular rotation velocities of the support base into electrical signals on two axes of rotation simultaneously. In addition, the valid signal level is increased compared to the noise interference level. This explains the expandability of the new modified microacoustomechanical gyroscope compared to the existing analogues. The operating principle of the modified gyro is specified in detail. The concept of its design and performance is explained in drawings. The proposed technical solution is protected by the Russian Federation patent for the invention. The proposed gyroscope can be used in the navigation, positioning and control systems of various mobile objects in aviation, rocket and space technology, robotics, etc.

micromechanical gyroscope, acoustic waves, surface acoustic waves, микромеханический гироскоп, акустические волны, поверхностные акустические волны

1. Matveev, V. А. Giroskop — eto prosto. [Gyroscope is a simple matter.] Moscow: Bauman MSTU Publ. House, 2012, 191 p. (in Russian).

2. Lukyanov, D.P., et al. Sovremennoe sostoyanie i perspektivy razvitiya tverdotel'nykh mikrogiroskopov na poverkhnostnykh akusticheskikh volnakh. [State of the art and prospects for the development of SAW-based solid-state gyros.] Gyroscopy and Navigation, 2011, no. 3 (74), pp. 75–87 (in Russian).

3. Evstifeev, M.I. Osnovnye etapy razrabotki otechestvennykh mikromekhanicheskikh giroskopov . [Main development stages of domestic micromechanical gyroscopes.] Journal of Instrument Engineering, 2011, vol. 54, no. 6, pp. 75–80 (in Russian).

4. Kalinin, V.A., et al. Matematicheskoe modelirovanie giroskopa na PAV [Mathematical modeling of SAW-based gyro.] Electronics: Science, Technology, Business. Spec. Iss., 2008, pp. 47–51 (in Russian).

5. Varadan, V. K., Varadan, V.V. Microsensors, microelectromechanical systems (MEMS), and electronics for smart structures and systems. Smart Materials and Structures, 2009, no. 9, pp. 953–972.

6. Kalinin, V.A., et al. P'yezoelektricheskiy giroskop: patent 2387951 Ros. Federatsiya: H03H9/25; G01C19/56. [Piezoelectric gyroscope.] Patent RF, no. 2387951, 2009 (in Russian).

7. Kalinin, V.A., et al. Giroskop na poverkhnostnykh akusticheskikh volnakh: patent 2390727 Ros. Federatsiya: G01P9/04; G01C19/56. [SAW-based gyro.] Patent RF, no. 2390727, 2010 (in Russian).

8. Aigner, R. Apparatus and method for detecting a rotation: patent 7895892 В2 US. Available at: http://www.uspto.gov (accessed: 08.11.16).

9. Varadan, V. K., et al. Micro-Electromechanical Gyroscope: patent 6984332 В2 US. Available at: http://www.uspto.gov (accessed: 08.11.16).

10. Vakhtin, Y.V., et al. Mikroakustomekhanicheskiy giroskop : patent 2543706 Ros. Federatsiya: G01C19/56; H03H9/25. [Micro-acoustomechanical gyroscope.] Patent RF, no. 2543706, 2015 (in Russian).

11. Miroshnichenko, I.P., Pogorelov, V.A., Sizov, V.P. Modifitsirovannyy mikromekhanicheskiy giroskop. [Modified micromechanical gyroscope.] Vestnik of DSTU, 2015, vol. 15, no. 2, pp. 73–77 (in Russian)