[1. FRADKOV, L. F., POGROMSKY A. Yu. 1999. Introduction to Control of Oscillations and Chaos. London: World Scientific Publishing Co. Pte. Ltd.10.1142/3412]Search in Google Scholar
[2. VRABEL, R., ABAS, M., KOPCEK, M., KEBISEK, M. 2013. Active Control of Oscillation Patterns in the Presence of Multiarmed Pitchfork Structure of the Critical Manifold of Singularly Perturbed System. Mathematical Problems in Engineering, Article ID 650354, 8 p.10.1155/2013/650354]Search in Google Scholar
[3. ATAY, F. M. 2002. Delayed-feedback control of oscillations in non-linear planar systems. International Journal of Control, 75(5), 297-304.]Search in Google Scholar
[4. PARK, S., TAN, CH.-W., KIM, H., HONG, S. K. 2009. Oscillation control algorithms for resonant sensors with applications to vibratory gyroscopes. Sensors, 9(8), 5952-5967.10.3390/s90805952331242422454566]Search in Google Scholar
[5. BAJCICAKOVA, I., KOPCEK, M., SUTOVA, Z. 2013. Design of Effective Numerical Scheme for Solving Systems with High-Speed Feedback. International Journal of Mathematical Analysis, 7(55), 2737-2744.]Search in Google Scholar
[6. MATLAB® Math. For Use with MATLAB®. Massachusets: The MathWorks, Inc., 2006.]Search in Google Scholar
[7. VRABEL, R., TANUSKA, P., VAZAN, P., SCHREIBER, P., LISKA, V. 2013. Duffing- Type Oscillator with a Bounded from above Potential in the Presence of Saddle-Center Bifurcation and Singular Perturbation: Frequency Control. Abstract and Applied Analysis, Article ID 848613, 7 p.10.1155/2013/848613]Search in Google Scholar
[8. VRABEL, R., ABAS, M. 2013. Frequency control of singularly perturbed forced Duffing’s oscillator. Journal of Dynamical and Control Systems, 17(3), 451-467. DOI: 10.1007/s10883-011-9125-010.1007/s10883-011-9125-0]Search in Google Scholar