Аннотация:
This article deals with the dynamics of a pulse-driven self-oscillating system — the Van
der Pol oscillator — with the pulse amplitude depending on the oscillator coordinate. In the
conservative limit the “stochastic web” can be obtained in the phase space when the function
defining this dependence is a harmonic one. The paper focuses on the case where the frequency of
external pulses is four times greater than the frequency of the autonomous system. The results of
a numerical study of the structure of both parameter and phase planes are presented for systems
with different forms of external pulses: the harmonic amplitude function and its power series
expansions. Complication of the pulse amplitude function results in the complication of the
parameter plane structure, while typical scenarios of transition to chaos visible in the parameter
plane remain the same in different cases. In all cases the structure of bifurcation lines near the
border of chaos is typical of the existence of the Hamiltonian type critical point. Changes in
the number and the relative position of coexisting attractors are investigated while the system
approaches the conservative limit. A typical scenario of destruction of attractors with a decrease
in nonlinear dissipation is revealed, and it is shown to be in good agreement with the theory
of 1:4 resonance. The number of attractors of period 4 seems to grow infinitely with the decrease
of dissipation when the pulse amplitude function is harmonic, while in other cases all attractors
undergo destruction at certain values of dissipation parameters after the birth of high-period
periodic attractors.