Add to ORKGWe present a formal framework for modeling evolutionary dynamics with special emphasis on the generation of diversity through branching of the evolutionary tree. Fitness is defined as the long term growth rate which is influenced by the biotic environment leading to frequency-dependent selection. Evolution can be described as a dynamics in space with variable number of dimensions corresponding to the number of different types present. The dynamics within a subspace is governed by the local fitness gradient. Entering a higher dimensional subspace is possible only at a particular type of attractors where the population undergoes evolutionary branching
Evolutionary branching—resident-mutant coexistence under disruptive selection—is one of the main con...
We develop a systematic toolbox for analyzing the adaptive dynamics of multidimensional traits in ph...
Evolutionary branching—resident-mutant coexistence under disruptive selection—is one of the main con...
We present a formal framework for modeling evolutionary dynamics with special emphasis on the genera...
We present a general framework for modeling adaptive traitdynamics in which we integrate various con...
We set out to explore a class of stochastic processes, called "adaptive dynamics", which supposedly ...
Darwinian dynamics based on mutation and selection from the core of mathematical models for adaptati...
Evolutionary branching occurs when frequency-dependent selection splits a phenotypically monomorphic...
Adaptive dynamics (AD) is a mathematical framework for dealing with eco-evolutionary problems, prima...
An "adaptive dynamics" modeling approach to the evolution of dominance-recessivity is presented. In ...
Adaptive Dynamics in two dimensional phenotype space is investigated by computer simulation. The mod...
We provide the link between population dynamics and the dynamics of Darwinian evolution via studying...
Evolution takes place in an evolutionary setting that typically involves interactions with other org...
Evolutionary branching—resident-mutant coexistence under disruptive selection—is one of the main con...
Evolutionary branching—resident-mutant coexistence under disruptive selection—is one of the main con...
Evolutionary branching—resident-mutant coexistence under disruptive selection—is one of the main con...
We develop a systematic toolbox for analyzing the adaptive dynamics of multidimensional traits in ph...
Evolutionary branching—resident-mutant coexistence under disruptive selection—is one of the main con...
We present a formal framework for modeling evolutionary dynamics with special emphasis on the genera...
We present a general framework for modeling adaptive traitdynamics in which we integrate various con...
We set out to explore a class of stochastic processes, called "adaptive dynamics", which supposedly ...
Darwinian dynamics based on mutation and selection from the core of mathematical models for adaptati...
Evolutionary branching occurs when frequency-dependent selection splits a phenotypically monomorphic...
Adaptive dynamics (AD) is a mathematical framework for dealing with eco-evolutionary problems, prima...
An "adaptive dynamics" modeling approach to the evolution of dominance-recessivity is presented. In ...
Adaptive Dynamics in two dimensional phenotype space is investigated by computer simulation. The mod...
We provide the link between population dynamics and the dynamics of Darwinian evolution via studying...
Evolution takes place in an evolutionary setting that typically involves interactions with other org...
Evolutionary branching—resident-mutant coexistence under disruptive selection—is one of the main con...
Evolutionary branching—resident-mutant coexistence under disruptive selection—is one of the main con...
Evolutionary branching—resident-mutant coexistence under disruptive selection—is one of the main con...
We develop a systematic toolbox for analyzing the adaptive dynamics of multidimensional traits in ph...
Evolutionary branching—resident-mutant coexistence under disruptive selection—is one of the main con...