State Dependent Multitype Spatial Branching Processes and their Longtime Behavior

Donald A. Dawson (Carleton University)
Andreas Greven (Universitat Erlangen-Nurnberg)

Abstract


The paper focuses on spatial multitype branching systems with spatial components (colonies) indexed by a countable group, for example $Z^d$ or the hierarchical group. As type space we allow continua and describe populations in one colony as measures on the type space. The spatial components of the system interact via migration. Instead of the classical independence assumption on the evolution of different families of the branching population, we introduce interaction between the families through a state dependent branching rate of individuals and in addition state dependent mean offspring of individuals. However for most results we consider the critical case in this work. The systems considered arise as diffusion limits of critical multiple type branching random walks on a countable group with interaction between individual families induced by a branching rate and offspring mean for a single particle, which depends on the total population at the site at which the particle in question is located.

The main purpose of this paper is to construct the measure valued diffusions in question, characterize them via well-posed martingale problems and finally determine their longtime behavior, which includes some new features. Furthermore we determine the dynamics of two functionals of the system, namely the process of total masses at the sites and the relative weights of the different types in the colonies as system of interacting diffusions respectively time-inhomogeneous Fleming-Viot processes. This requires a detailed analysis of path properties of the total mass processes.

In addition to the above mentioned systems of interacting measure valued processes we construct the corresponding historical processes via well-posed martingale problems. Historical processes include information on the family structure, that is, the varying degrees of relationship between individuals.

Ergodic theorems are proved in the critical case for both the process and the historical process as well as the corresponding total mass and relative weights functionals. The longtime behavior differs qualitatively in the cases in which the symmetrized motion is recurrent respectively transient. We see local extinction in one case and honest equilibria in the other.

This whole program requires the development of some new techniques, which should be of interest in a wider context. Such tools are dual processes in randomly fluctuating medium with singularities and coupling for systems with multi-dimensional components.

The results above are the basis for the analysis of the large space-time scale behavior of such branching systems with interaction carried out in a forthcoming paper. In particular we study there the universality properties of the longtime behavior and of the family (or genealogical) structure, when viewed on large space and time scales.

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Pages: 1-93

Publication Date: March 4, 2003

DOI: 10.1214/EJP.v8-126

References

  1. J. T. Cox, A. Greven. The finite systems scheme: An abstract theorem and a new example, Proceedings of CRM Conference on Measure valued processes. Stochastic partial differential equation and interacting Systems. CRM and Lecture Notes series of the American Mathematical Society. Vol. 5, 55-68, 1994.   Math. Review link
  2. J.T. Cox, A. Greven, T. Shiga. Finite and infinite systems of interacting diffusions. Prob. Theory and Rel. Fields,103, 165-197, 1995.   Math. Review link
  3. J.T. Cox, A. Greven, T. Shiga. Finite and infinite systems of interacting diffusions. Part II. Math. Nachrichten 192, 1998.   Math. Review link
  4. D. A. Dawson. Measure-valued Markov Processes, In Ecole d'Eté de Probabilités de Saint Flour XXI, Lecture Notes in Mathematics 1541, 1-261, Springer, 1993.   Math. Review link
  5. D. A. Dawson, A. Greven. Hierarchical models of interacting diffusions: Multiple time scales, Phase transitions and cluster-formation. Prob. Theor. and Rel. Fields, 96, 435-473, 1993. Math. Review link
  6. D. A. Dawson, A. Greven. Multiple space-time scale analysis for interacting branching models. Electronic Journal of Probability, Vol. 1, Paper no. 14, 1-84, 1996.   Math. Review link
  7. D. A. Dawson, A. Greven. Hierarchically interacting Fleming-Viot processes with selection and mutation: Multiple space time scale analysis and quasi-equilibria, Electronic Journal of Probability, Vol. 4, Paper 4, 1-81, 1999.   Math. Review link
  8. D. A. Dawson, A. Greven, J. Vaillancourt. Equilibria and Quasi-equilibria for infinite systems of Fleming-Viot processes. Math. Society, Vol. 347, Number 7, 1995.   Math. Review link
  9. D. A. Dawson, K. Hochberg. Wandering random measures in the Fleming-Viot model, Ann. Probab. 10, 554-580, 1982.   Math. Review link
  10. D. A. Dawson, E. A. Perkins. Historical Processes, Memoirs of the American Mathematical Society, vol. 93, no. 454, 1991.   Math. Review link
  11. D.A. Dawson and E.A. Perkins: Long-time behavior and coexistence in a mutually catalytic branching model, Ann. Probab. 26, 1088-1138, 1998.   Math. Review link
  12. S. N. Ethier, T. G. Kurtz. Markov Process - Characterization and Convergence, John Wiley and Sons, 1986.   Math. Review link
  13. S.N. Evans and E.A. Perkins. Measure-valued branching diffusions with singular interactions, Can. J. Math. 46(1), 120-168 , 1994.   Math. Review link
  14. K. Fleischmann, A. Greven. Time-space analysis of the cluster-formation in interacting diffusions. Electronic Journal of Probability, 1(6):1-46, 1996.   Math. Review link
  15. A. Greven. Phase Transition for the Coupled Branching Process, Part I: The ergodic theory in the range of finite second moments. Probab. Theory and Rel. Fields 87, 417-458, 1991.   Math. Review link
  16. I. Karatzas and S.E. Shreve. Brownian Motion and Stochastic Calculus, 2nd ed., Springer-Verlag, 1991.   Math. Review link
  17. U. Krengel. Ergodic Theorems. de Gruyter Studies in Mathematics 6, Berlin-New York, 1985.   Math. Review link
  18. T. M. Liggett and F. L. Spitzer. Ergodic theorems for coupled random walks and other systems with locally interacting components, Z. Wahrsch. verw. Gebiete, 56(4), 443ó468, 1981.   Math. Review link
  19. E.A. Perkins. Measure-valued branching diffusions with spatial interactions, Probab. Theory Relat. Fields, 94, 189-245, 1992.   Math. Review link
  20. E.A. Perkins: Conditional Dawson-Watanabe processes and Fleming-Viot processes, Seminar in Stochastic Processes, Birkhauser, 142-155, 1991. Math. Review link
  21. P. Révész. Random Walk in Random and Non-random environments, World Scientific, 1990. Math. Review link
  22. L.C.G. Rogers and D. Williams. Diffusions, Markov Processes and Martingales, volume 2, John Wiley and Sons, 1987.   Math. Review link
  23. D. Revuz and M. Yor. Continuous Martingales and Brownian Motion, Springer-Verlag, 1991.  Math. Review link
  24. T. Shiga. Ergodic theorems and exponential decay of sample paths for certain diffusions, Osaka J. Math. 29, 789-807,1992.   Math. Review link
  25. T. Shiga and A. Shimizu. Infinite-dimensional stochastic differential equations and their applications. J. Math. Kyoto Univ., 20, 395-416 1980.   Math. Review
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