Evaluating growth measures in an immigration process subject to binomial and geometric catastrophes. (English) Zbl 1143.92030
Summary: Populations are often subject to the effect of catastrophic events that cause mass removal. In particular, metapopulation models, epidemics, and migratory flows provide practical examples of populations subject to disasters (e.g., habitat destruction, environmental catastrophes). Many stochastic models have been developed to explain the behavior of these populations. Most of the reported results concern the measures of the risk of extinction and the distribution of the population size in the case of total catastrophes where all individuals in the population are removed simultaneously.
We investigate the basic immigration process subject to binomial and geometric catastrophes; that is, the population size is reduced according to a binomial or a geometric law. We carry out an extensive analysis including the first extinction time, number of individuals removed, survival time of a tagged individual, and maximum population size reached between two consecutive extinctions. Many explicit expressions are derived for these system descriptors, and some emphasis is put to show that some of them deserve extra attention.
We investigate the basic immigration process subject to binomial and geometric catastrophes; that is, the population size is reduced according to a binomial or a geometric law. We carry out an extensive analysis including the first extinction time, number of individuals removed, survival time of a tagged individual, and maximum population size reached between two consecutive extinctions. Many explicit expressions are derived for these system descriptors, and some emphasis is put to show that some of them deserve extra attention.
MSC:
92D25 | Population dynamics (general) |
60J25 | Continuous-time Markov processes on general state spaces |
37D45 | Strange attractors, chaotic dynamics of systems with hyperbolic behavior |
60J99 | Markov processes |
92D40 | Ecology |
60J70 | Applications of Brownian motions and diffusion theory (population genetics, absorption problems, etc.) |