New methods of characterizing spatio-temporal patterns in laboratory experiments

Kurtuldu, Huseyin

25 August 2010

Complex patterns arise in many extended nonlinear nonequilibrium systems in physics, chemistry and biology. Information extraction from these complex patterns is a challenge and has been a main subject of research for many years. We study patterns in Rayleigh-Benard convection (RBC) acquired from our laboratory experiments to develop new characterization techniques for complex spatio-temporal patterns. Computational homology, a new topological characterization technique, is applied to the experimental data to investigate dynamics by quantifying convective patterns in a unique way. The homology analysis is used to detect symmetry breakings between hot and cold flows as a function of thermal driving in experiments, where other conventional techniques, e.g., curvature and wave-number distribution, failed to reveal this asymmetry. Furthermore, quantitative information is acquired from the outputs of homology to identify different spatio-temporal states. We use this information to obtain a reduced dynamical description of spatio-temporal chaos to investigate extensivity and physical boundary effects in RBC. The results from homological analysis are also compared to other dimensionality reduction techniques such as Karhunen-Loeve decomposition and Fourier analysis.

Lyapunov dimension

Thermal convection

Pattern formation

Patter characterization techniques

Principal component analysis

Fourier analysis

Curvature

Image characterization techniques

Rayleigh-B´enard convection

Spatial analysis (Statistics)

Pattern formation (Physical sciences)

Homology theory

Differentiable dynamical systems