In this thesis, we investigate and develop a number of online learning

selection choice function based hyper-heuristic methodologies that attempt to

solve multi-objective unconstrained optimisation problems. For the first time,

we introduce an online learning selection choice function based hyperheuristic

framework for multi-objective optimisation. Our multi-objective

hyper-heuristic controls and combines the strengths of three well-known

multi-objective evolutionary algorithms (NSGAII, SPEA2, and MOGA), which

are utilised as the low level heuristics. A choice function selection heuristic

acts as a high level strategy which adaptively ranks the performance of those

low-level heuristics according to feedback received during the search process,

deciding which one to call at each decision point. Four performance

measurements are integrated into a ranking scheme which acts as a feedback

learning mechanism to provide knowledge of the problem domain to the high

level strategy. To the best of our knowledge, for the first time, this thesis

investigates the influence of the move acceptance component of selection

hyper-heuristics for multi-objective optimisation. Three multi-objective choice

function based hyper-heuristics, combined with different move acceptance

strategies including All-Moves as a deterministic move acceptance and the

Great Deluge Algorithm (GDA) and Late Acceptance (LA) as a nondeterministic

move acceptance function.

GDA and LA require a change in the value of a single objective at each

step and so a well-known hypervolume metric, referred to as D metric, is

proposed for their applicability to the multi-objective optimisation problems. D

metric is used as a way of comparing two non-dominated sets with respect to

the objective space. The performance of the proposed multi-objective

selection choice function based hyper-heuristics is evaluated on the Walking

Fish Group (WFG) test suite which is a common benchmark for multi-objective

optimisation. Additionally, the proposed approaches are applied to the vehicle

crashworthiness design problem, in order to test its effectiveness on a realworld

multi-objective problem. The results of both benchmark test problems

demonstrate the capability and potential of the multi-objective hyper-heuristic

approaches in solving continuous multi-objective optimisation problems. The

multi-objective choice function Great Deluge Hyper-Heuristic

(HHMO_CF_GDA) turns out to be the best choice for solving these types of

problems.