Prepublication version of the paper to appear in: Advanced Engineering Informatics 19 (2005) 263–280. ISSN: 1474-0346. 1 Interactive Visualisation for Decision Support and Evaluation of Robustness – In Theory and In Practice I.S.J. Packham a* , M.Y. Rafiq b , M.F. Borthwick b and S.L. Denham c a Lightwave Technologies Ltd, Innovation Centre, NovaUCD, University College Dublin, Belfield, Dublin 4, EIRE. b Department of Engineering, University of Plymouth, Drake’s Circus, Plymouth, PL4 8AA. UK. c Centre for Theoretical and Computational Neuroscience, University of Plymouth, Drake’s Circus, Plymouth, PL4 8AA. UK. * Corresponding author: Tel: +353-1-716-3625, Fax: +353-1- , email: ian.packham@ucd.ie . Abstract: An interactive visualisation system for engineering design incorporating a method to evaluate the robustness of solutions is described. The system uses genetic algorithms to generate a large number of alternative design solutions to the problem and an interface that supports multidimensional visualisation, allowing the designer to interact with the data. A clustering technique based on kernel density estimation is described that identifies clusters in terms of the design variables. The clustering technique combined with ‘negative’ genetic algorithm search is shown to successfully allow the user to evaluate the robustness of regions in continuous domains. The technique is illustrated on a continuous engineering design problem: rainfall runoff modelling. Most engineering design problems contain discrete and discontinuous variables and so the approach needs modification to be successful on such problems. Visualisation and user interaction is shown to be useful on discrete problems, particularly when the user creates their own clusters in a multiobjective problem. Evaluation of robustness on such problems is often only possible due to the knowledge of an experienced engineer. A practical example from the design of reinforced concrete biaxial columns illustrates how the system promotes decision support in discrete domains, in particular the implicit knowledge of the engineer, that is difficult to express in a model, can be used to make high-level design decisions. Thus knowledge discovery and evaluation of robustness is shown to be successfully achieved using visualisation and interaction in either continuous or discrete domains. Keywords: Interactive Visualisation, Knowledge Discovery, Robustness Evaluation, Genetic Algorithms.