Melnikov analysis of chaotic dynamics in an impact oscillator system

In this paper, the global dynamic characteristics of an impact oscillator in a class of complex non-smooth systems are discussed in depth by means of analytical and numerical analysis and the classical Melnikov theory. Firstly, the approximation method is used to obtain the fitting system, and the fitting system is compared with the original system. Subsequently, in order to further reveal the intrinsic chaos mechanism of the system, we apply the Melnikov method to determine the threshold conditions for the occurrence of homoclinic chaos in the system. Based on these threshold conditions, we systematically investigate the influence of key parameters such as recovery coefficient, excitation amplitude, excitation frequency and damping coefficient on the chaotic characteristics of the system. In particular, we analyze the transformation of system dynamics under different excitation amplitudes, and reveal the key role of excitation amplitude in regulating system stability. These research results provide new perspectives and tools for theoretical research in related fields, and also provide reference and guidance for the design and control of impact oscillators in practical engineering applications.