Biktasheva I V, Barkley D, Biktashev V N, Foulkes A J
Department of Computer Science, University of Liverpool, Liverpool L69 3BX, United Kingdom.
Phys Rev E Stat Nonlin Soft Matter Phys. 2010 Jun;81(6 Pt 2):066202. doi: 10.1103/PhysRevE.81.066202. Epub 2010 Jun 1.
Rotating spiral waves are a form of self-organization observed in spatially extended systems of physical, chemical, and biological nature. In the presence of a small perturbation, the spiral wave's center of rotation and fiducial phase may change over time, i.e., the spiral wave drifts. In linear approximation, the velocity of the drift is proportional to the convolution of the perturbation with the spiral's response functions, which are the eigenfunctions of the adjoint linearized operator corresponding to the critical eigenvalues λ=0,±iω . Here, we demonstrate that the response functions give quantitatively accurate prediction of the drift velocities due to a variety of perturbations: a time dependent, periodic perturbation (inducing resonant drift); a rotational symmetry-breaking perturbation (inducing electrophoretic drift); and a translational symmetry-breaking perturbation (inhomogeneity induced drift) including drift due to a gradient, stepwise, and localized inhomogeneity. We predict the drift velocities using the response functions in FitzHugh-Nagumo and Barkley models, and compare them with the velocities obtained in direct numerical simulations. In all cases good quantitative agreement is demonstrated.
旋转螺旋波是在物理、化学和生物性质的空间扩展系统中观察到的一种自组织形式。在存在小扰动的情况下,螺旋波的旋转中心和基准相位可能随时间变化,即螺旋波发生漂移。在线性近似中,漂移速度与扰动和螺旋响应函数的卷积成正比,螺旋响应函数是对应于临界特征值λ = 0,±iω的伴随线性化算子的特征函数。在此,我们证明响应函数能够对由于各种扰动引起的漂移速度给出定量准确的预测:随时间变化的周期性扰动(引起共振漂移);旋转对称性破缺扰动(引起电泳漂移);以及平移对称性破缺扰动(不均匀性引起的漂移),包括由于梯度、阶跃和局部不均匀性引起的漂移。我们使用FitzHugh-Nagumo模型和Barkley模型中的响应函数预测漂移速度,并将其与直接数值模拟中获得的速度进行比较。在所有情况下都证明了良好的定量一致性。
