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Autor(en): 
  • Jianhong Wu
  • Anatoly Swishchuk
  • Evolution of Biological Systems in Random Media: Limit Theorems and Stability 
     

    (Buch)
    Dieser Artikel gilt, aufgrund seiner Grösse, beim Versand als 3 Artikel!


    Übersicht

    Auf mobile öffnen
     
    Lieferstatus:   Auf Bestellung (Lieferzeit unbekannt)
    Veröffentlichung:  Oktober 2003  
    Genre:  Schulbücher 
     
    Bevölkerung und Demographie / Biomathematics / C / Epidemiology / Epidemiology & medical statistics / Human Genetics / Mathematical and Computational Biology / Mathematics and Statistics
    ISBN:  9781402015540 
    EAN-Code: 
    9781402015540 
    Verlag:  Springer EN 
    Einband:  Gebunden  
    Sprache:  English  
    Serie:  #18 - Mathematical Modelling: Theory and Applications  
    Dimensionen:  H 235 mm / B 155 mm / D  
    Gewicht:  1140 gr 
    Seiten:  218 
    Illustration:  XX, 218 p. 
    Bewertung: Titel bewerten / Meinung schreiben
    Inhalt:
    The book is devoted to the study of limit theorems and stability of evolving biologieal systems of "particles" in random environment. Here the term "particle" is used broadly to include moleculas in the infected individuals considered in epidemie models, species in logistie growth models, age classes of population in demographics models, to name a few. The evolution of these biological systems is usually described by difference or differential equations in a given space X of the following type and dxt/dt = g(Xt, y), here, the vector x describes the state of the considered system, 9 specifies how the system's states are evolved in time (discrete or continuous), and the parameter y describes the change ofthe environment. For example, in the discrete-time logistic growth model or the continuous-time logistic growth model dNt/dt = r(y)Nt(l-Nt/K(y)), N or Nt is the population of the species at time n or t, r(y) is the per capita n birth rate, and K(y) is the carrying capacity of the environment, we naturally have X = R, X == Nn(X == Nt), g(x, y) = r(y)x(l-xl K(y)) , xE X. Note that n t for a predator-prey model and for some epidemie models, we will have that X = 2 3 R and X = R , respectively. In th case of logistic growth models, parameters r(y) and K(y) normaIly depend on some random variable y.

      



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