Development of methods to model UAVS nonlinear automatic control systems

DOI: https://doi.org/10.46925//rdluz.30.10

Resumen

When modeling Automatic Control Systems (ACS) of an unmanned aerial vehicle (UAV), it is often necessary to take into account the nonlinearity of an aircraft's reaction when the controls drift, as well as the strong influence of various destabilizing factors that make the system go out of linear mode. When known analytical and numerical methods are used to analyze dynamic systems, it is problematic to obtain general solutions that are valid for the variable parameters of the system under study and, at the same time, provide the required error value. A method has been developed to model dynamic processes in automatic non-linear UAV control systems based on linear approximation by parts and crosslinking of partial solutions with consideration of the initial conditions. An example of using the technique to model the transition characteristics of an ACS UAV with a single non-linear link is considered. Based on the analysis of errors in the calculation of the transition process, the effectiveness of the proposed approach is shown.

Descargas

La descarga de datos todavía no está disponible.

Biografía del autor/a

G. S. Vasilyev, Universidad del Zulia
Profesor de la Universidad del Zulia
O. R. Kuzichkin, Professor of Belgorod State University, Belgorod, 308015, Russia
Belgorod State University, Belgorod, 308015, Russia
I. A. Kurilov, Vladimir State University, Vladimir, 600000, Russia
Professor of Vladimir State University, Vladimir, 600000, Russia
D. I. Surzhik, Vladimir State University, Vladimir, 600000, Russia
Professor of Vladimir State University, Vladimir, 600000, Russia

Citas

Advanced Control of Aircraft, Spacecraft and Rockets Ashish Tewar, 2011 John Wiley & Sons, Ltd. ISBN 978-0-470-74563-2, 454 p.

Austin, R. (2011). Unmanned aircraft systems: UAVS design, development and deployment (Vol. 54). John Wiley & Sons.

Balashkov, M. V. (2010). Development of methods for the analysis of piecewise linear systems and minimization of phase instability of transistor amplifiers: PhD thetis. - Moscow, Russia, - 148 p.

Bogachev, V. M., & Chapliga, V. M. (1976). On the calculation of periodic modes in systems with piecewise linear characteristics under harmonic influence. Radio engineering and electronics, 21(4), 906.

Gordin, A. G. (2000). Unmanned aerial vehicles as control objects. Ucheb.stipend. - Kharkiv: State aerospace university "Kharkiv. aviation institute", - 140 p.

Gutsevich, D. E. (2018). Modeling the behavior of an airplane-type aircraft with automatic control in various flight modes. Mathematical modeling, computer and field experiment in natural Sciences, 1.

Kuriki, Y., & Namerikawa, T. (2014). Formation control of UAVs with a fourth-order flight dynamics. SICE Journal of Control, Measurement, and System Integration, 7(2), 74-81.

Kurilov, I. A., Vasilyev, G. S., & Harchuk, S. M. (2010). Dynamic characteristics analysis of signal converters based on continuous piecewise linear functions. Nauchno-tekhnichesky vestnik Povolzhya, (1), 100-104.

Kurilov, I. A., Vasilyev, G. S., Kharchuk, S. M., & Surzhik, D. I. (2012). Vasilyev G. S. Investigation of the stability of a signal converter based on continuous piecewise linear functions. Radio Engineering and telecommunication systems, 1, 4-7.

Lebedev A. A., Chernobrovkin L. S. (1973). Flight Dynamics of unmanned aerial vehicles. – Study book for universities. - Moscow: Mashinostroenie,. – 616 p.

Marino, M., Gardi, M. A., Sabatini, R., Watkins, M. D., & Watkins, M. R. (2016). DEVELOPMENT OF A VALIDATED DYNAMICS MODEL FOR THE STOPROTOR UAV REPORT 2: Rotary Wing Configuration Experimental and Numerical Methods.

Moiseev, V. S. (2013). Applied theory of control of unmanned aerial vehicles: monograph. Kazan: GBU «Republican Center for Monitoring the Quality of Education»(Series «Modern Applied Mathematics and Informatics»).–768 p.

Raffo, G. V., Ortega, M. G., & Rubio, F. R. (2010). An integral predictive/nonlinear H∞ control structure for a quadrotor helicopter. Automatica, 46(1), 29-39.

Vasilyev, G. S., Kurilov, I. A., Kharchuk, S. M., & Surzhik, D. I. (2013, September). Analysis of dynamic characteristics of the nonlinear amplitude-phase converter at complex input influence. In 2013 International Siberian Conference on Control and Communications (SIBCON) (pp. 1-4). IEEE.

Vasilyev, G., Kurilov, I., & Kharhuk, S. (2011, September). Research of static characteristics of converters of signals with a nonlinear control device. In 2011 International Siberian Conference on Control and Communications (SIBCON) (pp. 93-96). IEEE.

Xiang, X., Liu, C., Su, H., & Zhang, Q. (2017). On decentralized adaptive full-order sliding mode control of multiple UAVs. ISA transactions, 71, 196-205.

Zheng, E. H., Xiong, J. J., & Luo, J. L. (2014). Second order sliding mode control for a quadrotor UAV. ISA transactions, 53(4), 1350-1356.

Publicado
2020-07-04
Cómo citar
Vasilyev, G. S., Kuzichkin, O. R., Kurilov, I. A., & Surzhik, D. I. (2020). Development of methods to model UAVS nonlinear automatic control systems. Revista De La Universidad Del Zulia, 11(30), 137-147. https://doi.org/10.46925//rdluz.30.10
Número
Vol. 11 Núm. 30 (2020): Revista de la Universidad del Zulia, Número 30, Mayo-Agosto 2020, Ciencias Exactas, Naturales y de la Salud
Sección
Artículos

Copyright

La Revista de la Universidad del Zulia declara que reconoce los derechos de los autores de los trabajos originales que en ella se publican; dichos trabajos son propiedad intelectual de sus autores. Los autores preservan sus derechos de autoría y comparten sin propósitos comerciales, según la licencia adoptada por la revista..

 

Esta obra está bajo la licencia:
Creative Commons Reconocimiento-NoComercial-CompartirIgual 4.0 Internacional (CC BY-NC-SA 4.0)