Multistability, transient chaos and hyperchaos, synchronization, and chimera states in wireless magnetically coupled VDPCL oscillators

“…Also, in our recent papers, we show that chaotic-based inductor oscillators can be wirelessly controlled when coupled magnetically to another external coil supplied by a sinusoidal voltage [15]. Other recent papers have also shown that magnetic coupling can be used to generate very rich dynamics in unconnected coupled chaotic oscillators including synchronization and chimera state [16,17].…”

“…are respectively the coupling coefficient between inductors 𝐿 1 and 𝐿 2 . Since the model is based on unconnected circuits, these coupling coefficients depend on the distance between each oscillator and the geometry of the coils [15][16][17]. Also, the current-voltage characteristic of the nonlinear resistor is given by 𝑖(𝑉 1 ) = 𝑎𝑉 1 + 𝑏𝑉 1 3 with 𝑎 < 0 and 𝑏 > 0.…”

“…Chimera state has been first observed in non-local coupling [33][34][35][36][37] and it was believed that a nonlocal coupling topology is the necessary condition for the appearance of chimera states in complex networks. However, recent studies have demonstrated the emergence of chimera states in a variety of topologies including global [38][39][40][41][42][43]17] and local (nearest-neighbor) [44,45,31] coupled oscillators, and, for different types of individual dynamics such as limit-cycle oscillators [45,46] chaotic oscillators [47], chaotic maps [48], hyperchaotic time delay systems [49], and even in neuronal systems exhibiting bursting dynamics [50][51][52]. A pioneering work that unveils this dynamical pattern is the work of Bathogoh and Kuramuto [53].…”

Complex spatiotemporal dynamics in a network of locally and magnetically coupled VDPCL oscillators

“…Also, in our recent papers, we show that chaotic-based inductor oscillators can be wirelessly controlled when coupled magnetically to another external coil supplied by a sinusoidal voltage [15]. Other recent papers have also shown that magnetic coupling can be used to generate very rich dynamics in unconnected coupled chaotic oscillators including synchronization and chimera state [16,17].…”

“…are respectively the coupling coefficient between inductors 𝐿 1 and 𝐿 2 . Since the model is based on unconnected circuits, these coupling coefficients depend on the distance between each oscillator and the geometry of the coils [15][16][17]. Also, the current-voltage characteristic of the nonlinear resistor is given by 𝑖(𝑉 1 ) = 𝑎𝑉 1 + 𝑏𝑉 1 3 with 𝑎 < 0 and 𝑏 > 0.…”

“…Chimera state has been first observed in non-local coupling [33][34][35][36][37] and it was believed that a nonlocal coupling topology is the necessary condition for the appearance of chimera states in complex networks. However, recent studies have demonstrated the emergence of chimera states in a variety of topologies including global [38][39][40][41][42][43]17] and local (nearest-neighbor) [44,45,31] coupled oscillators, and, for different types of individual dynamics such as limit-cycle oscillators [45,46] chaotic oscillators [47], chaotic maps [48], hyperchaotic time delay systems [49], and even in neuronal systems exhibiting bursting dynamics [50][51][52]. A pioneering work that unveils this dynamical pattern is the work of Bathogoh and Kuramuto [53].…”

Complex spatiotemporal dynamics in a network of locally and magnetically coupled VDPCL oscillators

“…Because it can be applied in multiple fields, studying the transient behavior of a chaotic system is more instructive for practical applications. [34] However, most chaotic systems have very few transient behaviors, typically only periodic to chaotic transitions, [35,36] or transitions from chaos to periodicity. [37] Although a memristive chaotic system with four transient behaviors has recently been reported, [34] and scholars have discovered systems with two transient behaviors coexisting, [38] as well as some other special transient behaviors, [39][40][41] such systems are still rare.…”

Rucklidge-based memristive chaotic system: Dynamic analysis and image encryption

Transient dynamics in a quasiperiodically forced nonsmooth dynamical system