Extending previous analyses on function classes like linear functions, we analyze how the simple (1+1) evolutionary algorithm optimizes pseudo-Boolean functions that are strictly monotonic. These functions have the property that whenever only 0-bits are changed to 1, then the objective value strictly increases. Contrary to what one would expect, not all of these functions are easy to optimize. The choice of the constant c in the mutation probability p(n)=c/n can make a decisive difference. We show that if c<1, then the (1+1) EA finds the optimum of every such function in iterations. For c=1, we can still prove an upper bound of O(n3/2). However, for , we present a strictly monotonic function such that the (1+1) EA with overwhelming prob...
We study evolutionary algorithms in a dynamic setting, where for each generation a different fitness...
Abstract. Evolutionary Algorithms (EAs) are successfully applied for optimization in discrete search...
We study the $(1,\lambda)$-EA with mutation rate $c/n$ for $c\le 1$, where the population size is ad...
Extending previous analyses on function classes like linear functions, we analyze how the simple (1+...
Extending previous analyses on function classes like linear functions, we analyze how the simple (1+...
We study the (1, λ)-EA with mutation rate c/n for c ≤ 1, where the population size is adaptively con...
We regard the classical problem how the (1+1)~Evolutionary Algorithm optimizes an arbitrary linear p...
The typical view in evolutionary biology is that mutation rates are minimised. Contrary to that view...
AbstractMany experimental results are reported on all types of Evolutionary Algorithms but only few ...
A common view in evolutionary biology is that mutation rates are minimised. However, studies in comb...
Many experimental results are reported on all types of Evolutionary Algorithms but only few results ...
Many experimental results are reported on all types of Evolutionary Algorithms but only few results ...
AbstractEvolutionary algorithms are applied as problem-independent optimization algorithms. They are...
We reconsider a classical problem, namely how the (1+1) evolutionary algorithm optimizes the LEADING...
International audienceTo gain a better theoretical understanding of how evolutionary algorithms (EAs...
We study evolutionary algorithms in a dynamic setting, where for each generation a different fitness...
Abstract. Evolutionary Algorithms (EAs) are successfully applied for optimization in discrete search...
We study the $(1,\lambda)$-EA with mutation rate $c/n$ for $c\le 1$, where the population size is ad...
Extending previous analyses on function classes like linear functions, we analyze how the simple (1+...
Extending previous analyses on function classes like linear functions, we analyze how the simple (1+...
We study the (1, λ)-EA with mutation rate c/n for c ≤ 1, where the population size is adaptively con...
We regard the classical problem how the (1+1)~Evolutionary Algorithm optimizes an arbitrary linear p...
The typical view in evolutionary biology is that mutation rates are minimised. Contrary to that view...
AbstractMany experimental results are reported on all types of Evolutionary Algorithms but only few ...
A common view in evolutionary biology is that mutation rates are minimised. However, studies in comb...
Many experimental results are reported on all types of Evolutionary Algorithms but only few results ...
Many experimental results are reported on all types of Evolutionary Algorithms but only few results ...
AbstractEvolutionary algorithms are applied as problem-independent optimization algorithms. They are...
We reconsider a classical problem, namely how the (1+1) evolutionary algorithm optimizes the LEADING...
International audienceTo gain a better theoretical understanding of how evolutionary algorithms (EAs...
We study evolutionary algorithms in a dynamic setting, where for each generation a different fitness...
Abstract. Evolutionary Algorithms (EAs) are successfully applied for optimization in discrete search...
We study the $(1,\lambda)$-EA with mutation rate $c/n$ for $c\le 1$, where the population size is ad...