We consider the problem of initiation of a propagating wave in a one-dimensional excitable fibre. In the Zeldovich-Frank-Kamenetsky equation, a.k.a. Nagumo equation, the key role is played by the "critical nucleus" solution whose stable manifold is the threshold surface separating initial conditions leading to initiation of propagation and to decay. Approximation of this manifold by its tangent linear space yields an analytical criterion of initiation which is in a good agreement with direct numerical simulations.PACS numbers: 87.10.+e, 02.90.+p Threshold phenomena are widespread in bistable dissipative systems. If such a system is spatially extended, then fronts switching from one local state to the other can propagate. Propagating fronts, or trigger waves, play important roles in such diverse physical situations as selfheating in metals and superconductors, phase transitions, combustion and other chemical reaction waves, and biological signalling systems [1-6] to name a few. In biology and chemistry they often appear as a fast stage of pulse waves in "excitable systems" [3,[6][7][8]. The question of existence of such waves in particular mathematical models is well studied. However, whether a propagating wave will actually be observed depends on initial conditions. Understanding conditions of initiation of propagating fronts or pulses is very important in applications. In heart such waves trigger coordinated contraction of the muscle and failure of initiation can cause or contribute to serious or fatal medical conditions, or render inefficient the work of pacemakers or defibrillators [9]. In combustion, understanding of initiation is of critical importance for safety in storage and transport of combustible materials [10].Mathematically, after the external initiating stimulus has finished, the problem is reduced to classification of initial conditions that will or will not lead to a propagating wave solution. This problem is difficult as it is essentially non-stationary, spatially extended and nonlinear, and does not have any helpful symmetries. Yet the problem is so important that analytical answers are highly desirable even if not very accurate.Early attempts of analytical treatment of the initiation problems, including the spatially extended ones, used linear description supplemented with heuristic conditions to represent the threshold [11][12][13][14][15] and, more recently, lowdimensional Galerkin style approximations of the partial differential equations [16,17] In the last two decades, this problem has been analysed from the dynamical systems theory viewpoint [16][17][18][19][20][21][22]. These studies identified the importance of certain "critical solutions", whose codimension-1 (center-)stable manifold acts as the critical surface separating the basins of attraction of initiation and decay. This understanding was used in sophisticated numerical methods of calculating initiation thresholds, e.g. [21].Here we propose a practical method of defining the initiation criteria analytically. The idea is based...
