Scholar iON
Academic Synthesis
The selected scholarly papers explore diverse areas within the nonlinear sciences, each contributing unique insights into complex systems' dynamics. Celani et al. (2005) investigate polymer dynamics in shear flow, utilizing numerical simulations to enhance understanding of polymer behavior, aligning with experimental findings. Fyodorov and Sommers (2000) examine the spectral properties of random contractions, deriving statistical descriptions that elucidate behavior in non-Hermitian random matrices. Berkolaiko et al. (2001) delve into quantum graph theory, using periodic-orbit theory to refine understanding of form factors in quantum systems, with implications for random-matrix theory. Lastly, San-MartΓn (2005) connects saddle-node bifurcation cascades to intermittency within the logistic equation, offering mathematical frameworks that deepen comprehension of bifurcation phenomena. Collectively, these studies underscore the significance of theoretical and numerical approaches in advancing knowledge of nonlinear dynamics across different physical and mathematical contexts.
We study the dynamics of a single polymer subject to thermal fluctuations in a linear shear flow. The polymer is modeled as a finitely extendable nonlinear elastic FENE dumbbell. Both orientation and elongation dynamics are investigated numerically as a function of the shear strength, by means of a new efficient integration algorithm. The results are in agreement with recent experiments.
Random contractions (sub-unitary random matrices) appear naturally when considering quantized chaotic maps within a general theory of open linear stationary systems with discrete time. We analyze statistical properties of complex eigenvalues of generic $N\times N$ random matrices $\hat{A}$ of such a type, corresponding to systems with broken time-reversal invariance. Deviations from unitarity are characterized by rank $M\le N$ and a set of eigenvalues $0<T_i\le 1, i=1,...,M$ of the matrix $\hat{T}=\hat{\bf 1}-\hat{A}^{\dagger}\hat{A}$. We solve the problem completely by deriving the joint probability density of $N$ complex eigenvalues and calculating all $n-$ point correlation functions. In the limit $N>>M,n$ the correlation functions acquire the universal form found earlier for weakly non-Hermitian random matrices.
Using periodic-orbit theory beyond the diagonal approximation we investigate the form factor, $K(Ο)$, of a generic quantum graph with mixing classical dynamics and time-reversal symmetry. We calculate the contribution from pairs of self-intersecting orbits that differ from each other only in the orientation of a single loop. In the limit of large graphs, these pairs produce a contribution $-2Ο^2$ to the form factor which agrees with random-matrix theory.
The presence of saddle-node bifurcation cascade in the logistic equation is associated with an intermittency cascade; in a similar way as a saddle-node bifurcation is associated with an intermittency. We merge the concepts of bifurcation cascade and intermittency. The mathematical tools necessary for this process will describe the structure of the Myrberg-Feigenbaum point.
Using standard definitions of chaos (as positive Kolmogorov-Sinai entropy) and diffusion (that multiple time distribution functions are Gaussian), we show numerically that both chaotic and nonchaotic systems exhibit diffusion, and hence that there is no direct logical connection between the two properties. This extends a previous result for two time distribution functions.
Difference control schemes for controlling unstable fixed points become important if the exact position of the fixed point is unavailable or moving due to drifting parameters. We propose a memory difference control method for stabilization of a priori unknown unstable fixed points by introducing a memory term. If the amplitude of the control applied in the previous time step is added to the present control signal, fixed points with arbitrary Lyapunov numbers can be controlled. This method is also extended to compensate arbitrary time steps of measurement delay. We show that our method stabilizes orbits of the Chua circuit where ordinary difference control fails.