Truncation Selection and Gaussian EDA: Bounds for Sustainable Progress in High-Dimensional Spaces

Abstract: Abstract. In real-valued estimation-of-distribution algorithms, the Gaussian distribution is often used along with maximum likelihood (ML) estimation of its parameters. Such a process is highly prone to premature convergence. The simplest method for preventing premature convergence of Gaussian distribution is enlarging the maximum likelihood estimate of σ by a constant factor k each generation. Such a factor should be large enough to prevent convergence on slopes of the fitness function, but should not be too … Show more

“…However, with increasing dimensionality, the value of k min grows faster than k max for all values of τ , and for dimensions greater then 5 there is no admissible k (which would ensure effective traversing of slopes and focusing to the optimum in the same time). This is in accordance with the results in [13] and [14]. The situation for C iso distribution is even better, see Fig.…”

“…In this article, an approach of [14] is used where the combined effect of the selection and variation is taken into account.…”

“…Although [13] theoretically deduced bounds for k in case of 1D Gaussian distribution, in [14] it was shown that the process sketched above does not work with increasing dimensionality, since the interval of admissible k diminishes and eventually vanishes. This is due to the fact that the variance after selection in the neighborhood of the valley (sphere function) increases with dimensionality, thus k max must be successively smaller and eventually gets lower than k min .…”

“…1, that suggests enlarging the population variance by a constant factor each generation, was studied in [12] where the minimal values of the 'amplification coefficient' were determined by a search in 1D case. In [13], the theoretical model of the algorithm behavior in 1D was used to derive the minimal and maximal admissible values for k. However, in [14] it was shown experimentaly that a constant multiplier does not ensure the desired properties of the algorithm when increasing the dimensionality of the search space.…”

Preventing Premature Convergence in a Simple EDA Via Global Step Size Setting

“…However, with increasing dimensionality, the value of k min grows faster than k max for all values of τ , and for dimensions greater then 5 there is no admissible k (which would ensure effective traversing of slopes and focusing to the optimum in the same time). This is in accordance with the results in [13] and [14]. The situation for C iso distribution is even better, see Fig.…”

“…In this article, an approach of [14] is used where the combined effect of the selection and variation is taken into account.…”

“…Although [13] theoretically deduced bounds for k in case of 1D Gaussian distribution, in [14] it was shown that the process sketched above does not work with increasing dimensionality, since the interval of admissible k diminishes and eventually vanishes. This is due to the fact that the variance after selection in the neighborhood of the valley (sphere function) increases with dimensionality, thus k max must be successively smaller and eventually gets lower than k min .…”

“…1, that suggests enlarging the population variance by a constant factor each generation, was studied in [12] where the minimal values of the 'amplification coefficient' were determined by a search in 1D case. In [13], the theoretical model of the algorithm behavior in 1D was used to derive the minimal and maximal admissible values for k. However, in [14] it was shown experimentaly that a constant multiplier does not ensure the desired properties of the algorithm when increasing the dimensionality of the search space.…”

Preventing Premature Convergence in a Simple EDA Via Global Step Size Setting

Stochastic Local Search Techniques with Unimodal Continuous Distributions: A Survey

Stochastic local search in continuous domains