The Correlation of Gyroscope Axial Velocities

Source:
By:Ryspek Usubamatov

DOI: https://doi.org/10.30564/jmmmr.v6i1.5509

Abstract:

In engineering, all movable expanse revolving objects manifest gyroscopic effects. These effects are created by the action of the outer load on the revolving items whose rotating mass originates eight inertial torques about two axes. Two torques of centrifugal forces, one torque of the Coriolis force originated by the rotating distributed mass, and the torque of the change in the angular momentum of the center mass act about each axis. The inertial torques activate rotations of the gyroscope by the determined correlation. Inertial torques depend on their geometry and orientation at the spatial coordinate system. The known analytical model for the rotation of the revolving disc about axes contains a mechanical error. This error was obtained by the incorrect integration of the centrifugal inertial torque. The corrected inertial torque yields the accurate expression for the interacted rotations of the revolving disc about axes.

References:

[1] Cordeiro, F.J.B., 2015. The Gyroscope [Internet]. Createspace: NV, USA. Available from: https://www.google.kg/books/edition/The_Gyroscope/P31ZvwEACAAJ?hl=en [2] Greenhill, G., 2015. Report on gyroscopic theory. Relink Books, Fallbrook: CA, USA. [3] Scarborough, J.B., 2014. The gyroscope theory and applications. Nabu Press: London. [4] Weinberg, H., 2011. Gyro Mechanical Performance: The Most Important Parameter [Internet]. Available from: https://www.analog.com/en/technical-articles/gyro-mechanical-performance.html [5] Hibbeler, R.C., Yap, K.B., 2013. Mechanics for engineers-statics and dynamics, 13th edition. Prentice Hall, Pearson: Singapore. [6] Gregory, D.R., 2006. Classical mechanics. Cambridge University Press: New York. [7] Taylor, J.R., 2005. Classical mechanics. University Science Books: California, USA. [8] Aardema, M.D., 2005. Analytical dynamics:Theory and application. Academic/Plenum Publishers: New York. [9] Liang, W.C., Lee, S.C., 2013. Vorticity, gyroscopic precession, and spin-curvature force. Physical Review D. 87, 044024. [10]LeMoyne, R., Mastroianni, T., McCandless, C., 2018. Implementation of a smartphone as a wearable and wireless accelerometer and gyroscope platform for ascertaining deep brain stimulation treatment efficacy of parkinson’s disease through machine learning сlassification. Advances in Parkinson’s Disease. 7, 19-30. DOI: https://doi.org/10.4236/apd.2018.72003 [11] Yong, C.Y., Sudirman, R., Mahmood, N.H., et al., 2013. Motion classification using proposed principle component analysis hybrid k-means clustering. Engineering. 5(5B), 25-30. DOI: https://doi.org/10.4236/eng.2013.55B006 [12]Crassidis, J.L., Markley, F.L., 2016. Three-axis attitude estimation using rate-integrating gyroscopes. Journal of Guidance, Control, and Dynamics. 39, 1513-1526. [13]Nanamori, Y., Takahashi, M., 2015. An integrated steering law considering biased loads and singularity for control moment gyroscopes. AIAA guidance, navigation, and control conference 2015, MGNC 2015—Held at the AIAA SciTech Forum 2015. American Institute of Aeronautics and Astronautics Inc.: USA. [14]Usubamatov, R., Allen, D., 2022. Corrected inertial torques of gyroscopic effects, Hindawi. Advances in Mathematical Physics. 1-7. DOI: https://doi.org/10.1155/2022/3479736 [15]Usubamatov, R. (editor), 2015. Mathematical model for gyroscope’s Gimbal motions. 4th International Conference on Advances in Engineering Sciences & Applied Mathematics (ICAESAM’2015); 2015 Dec 08-09; Kuala Lumpur (Malaysia). p. 41-44. [16]Usubamatov, R., 2022. Theory of gyroscope effects for rotating objects. Springer, Cham: Switzerland.