The run-Time of evolutionary algorithms (EAs) is typically dominated by fitness evaluation. This is particularly the case when the genotypes are complex, such as in genetic programming (GP). Evaluating multiple offspring in parallel is appropriate in most types of EAs and can reduce the time incurred by fitness evaluation proportional to the number of parallel processing units. The most naive approach maintains the synchrony of evolution as employed by the vast majority of EAs, requiring an entire generation to be evaluated before progressing to the next generation. Heterogeneity in the evaluation times will degrade the performance, as parallel processing units will idle until the longest evaluation has completed. Asynchronous parallel evol...
This paper considers the most simple type of parallel GA: a single-population master-slave implement...
The use of multiple populations in Genetic Programming is an area that is just beginning to be inves...
153 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 1999.Parallel implementations of g...
Many important problem classes lead to large variations in fitness evaluation times, such as is ofte...
Genetic Programming (GP) is a type of Evolutionary Algorithm (EA) commonly employed for automated pr...
Evolutionary Algorithms (EAs) are inherently parallel due to their ability to simultaneously evaluat...
Traditionally, reducing complexity in Machine Learning promises benefits such as less overfitting. H...
The parallel genetic algorithm (PGA) uses two major modifications compared to the genetic algorithm....
This paper examines the effects of relaxed synchronization on both the numerical and parallel effici...
Parallel genetic algorithms (PGAs) have been traditionally used to extend the power of serial geneti...
As genetic algorithms (GAs) are used to solve harder problems, it is becoming necessary to use bette...
International audienceMaster-slave parallelization of Evolutionary Algorithms (EAs) is straightforwa...
Cartesian genetic programming (CGP) is a form of genetic programming where candidate programs are re...
Evolutionary computing has been used for many years in the form of evolutionary algorithms (EA)---of...
Parallel genetic algorithms (PGA) use two major modifications compared to the genetic algorithm. Fir...
This paper considers the most simple type of parallel GA: a single-population master-slave implement...
The use of multiple populations in Genetic Programming is an area that is just beginning to be inves...
153 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 1999.Parallel implementations of g...
Many important problem classes lead to large variations in fitness evaluation times, such as is ofte...
Genetic Programming (GP) is a type of Evolutionary Algorithm (EA) commonly employed for automated pr...
Evolutionary Algorithms (EAs) are inherently parallel due to their ability to simultaneously evaluat...
Traditionally, reducing complexity in Machine Learning promises benefits such as less overfitting. H...
The parallel genetic algorithm (PGA) uses two major modifications compared to the genetic algorithm....
This paper examines the effects of relaxed synchronization on both the numerical and parallel effici...
Parallel genetic algorithms (PGAs) have been traditionally used to extend the power of serial geneti...
As genetic algorithms (GAs) are used to solve harder problems, it is becoming necessary to use bette...
International audienceMaster-slave parallelization of Evolutionary Algorithms (EAs) is straightforwa...
Cartesian genetic programming (CGP) is a form of genetic programming where candidate programs are re...
Evolutionary computing has been used for many years in the form of evolutionary algorithms (EA)---of...
Parallel genetic algorithms (PGA) use two major modifications compared to the genetic algorithm. Fir...
This paper considers the most simple type of parallel GA: a single-population master-slave implement...
The use of multiple populations in Genetic Programming is an area that is just beginning to be inves...
153 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 1999.Parallel implementations of g...