Abstract:
Probability Collectives (PC) employ multiple agents to distribute sampling moves
through using probability distributions over a solution space. This multi-agent
systems (MAS) affords the advantage of parallel and distributed load to intelligent
agents coordinated by PC for optimal search. This thesis addresses single and multiobjective
hybrid learning algorithms based on probability collectives, which solve
single and multi-objective global optimization problems. In the first hybrid learning
model, search guided by adaptive heuristic method of Differential Evolution (DE)
algorithm based on the modified PC is implemented to tackle large-scale continuous
optimization problems consisting of classical and intractable single-objective
functions. DE/rand/1 classical scheme maintains appropriate search directions and
improve MAS’s performance by adaptive vector mutation for different search
regions. Two well-known benchmark problem sets, 23 classical benchmark problems
and CEC2005 contest instances, were used and experimental results reveal that the
presented approach is capable of integrating the collective learning methodology
effectively and competitively in the proposed agent-based model.
In the second proposed approach, a PC-based multi-objective optimization algorithm
is implemented using various efficient techniques and naturally promoted search
operators to find the set of solutions of MOPs that achieve the best compromise with
regard to the whole set of objectives. This method uses weighted aggregation
technique to decompose multi-objective solutions into a single objective and created
population evolves by evolutionary operators based on PC, with which the objectives
are optimized in a collaborative manner. Multi-objective Evolutionary Algorithm
iv
Based on Decomposition (MOEA/D) learns and samples probabilistic distribution
from PC stochastic engine. In terms of the employment of useful information from
neighbors, decomposition mechanism adopted in multi-objective optimization lumps
various problems into single objective concept. PC approach is then provided with
initial local search for enhancing the performance of MOEA/D framework.
Additionally, a combined mutation operator of the framework is also proposed as the
global optimizer to approximate the Pareto optimal set. This algorithm effectively
explores the feasible search space and enhances the convergence for the true Paretooptimal
region. To validate the hybrid algorithm, the experimental study is conducted
on the set of multi-objective unconstrained benchmark problems provided for
CEC2009 contest, and its performance is compared with some state-of-the-art
metaheuristic algorithms. In addition, the simulation results demonstrated that the
proposed approach performs competitively with state-of-the-art multi-objective
algorithms.
Keywords: Probability Collectives, Multi-agent systems, Differential Evolution,
Single-objective Problem, Multi-objective Problem, MOEA/D.
Description:
Doctor of Philosophy in Computer Engineering. Thesis (M.S.)--Eastern Mediterranean University, Faculty of Engineering, Dept. of Computer Engineering, 2016. Supervisor: Assist. Prof. Dr. Ahmet Ünveren.