Developing better designs using computational intelligence
There's an increasing demand for engineers to make the 'best' possible design decisions while decreasing costs and at a faster pace. This requires knowledge of methods in design optimisation which have become an integral part of product design and decision-making activities when developing mechanical structures, devices or systems.
Traditional design optimisation relied on manually identifying the right combination of design variables. This process is time-consuming and involves a trial-and-error approach to satisfy design objectives. Design optimisation allows for thousands of designs to be experimented with on a computer using mathematical formulations and simulations to find the optimal design relative to a set of performance objectives and constraints. Maximising factors such as productivity, strength and reliability, optimisation techniques have helped automate and improve efficiencies while reducing costs in product design, manufacturing processes and project planning.
Associated schools, institutes & centres
Impact
We're developing cutting-edge, practicaland efficient algorithms and frameworks to support multidisciplinary optimisation. These design optimisation methods, which provide solutions for a wide variety of design problems, address fundamental challenges and uncertainties in the optimisation process including:
the presence of multiple conflictingperformance criteriasuch as minimum cost, maximum reliability, and maximum strength
the presence of several design variables and/ordesign constraints
computationally expensive simulations
highlynon-linearprogrammingor black-box response functions
hierarchical objectives involving decision-making at multiple levels.
Our research is frequently published in leading journals such as the Institute of Electrical and Electronic Engineers (IEEE) Transactions on Evolutionary Computation Journal and the American Society of Mechanical Engineers (ASME) Journal of Mechanical Design.
We're running several externally funded projects which include the Australian Research Council (ARC) Discovery projects, Future Fellowshipand the Endeavour Fellowship.
Competitive advantage
- A combination of expertise and experience in diverse fields such as evolutionary computation, engineering designand operations research.
- Collaborations with leading researchers in the field globally.
Successful applications
Our research is successfully applied across several engineering applications including but not limited to:
- underwater vehicle design
- ship hull design
- scramjet geometries (Australian space research program)
- oil production planning
- wind-farm layout
- hybrid car controllers and energy management (Honda research institute).
Partners
We collaborate with a wide range of university and industry partners including:
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Rahi, K.H., Singh, H.andRay, T., “,”ASME Journal of Mechanical Design, in press (available online), 2020.
Singh, H., “,” IEEE Transactions on Evolutionary Computation, vol 24, issue 3, pp. 603-610, 2020.
Elsayed, S., Sarker, R., Essam, D., CoelloCoello, C.Information Sciences, vol. 523, pp. 77- 90, 2020
Singh, H., Bhattacharjee, K.S., and Ray, T., “,”IEEE Transactions on Evolutionary Computation, vol 23, issue 5, pp. 904-912, 2019.
Habib, A., Singh, H., Chugh, T., Ray, T., and Miettinen, K., “,”IEEE Transactions on Evolutionary Computation, vol. 23, issue 6, pp. 1000-1014, 2019.
Bhattacharjee, K.S., Singh, H. and Ray, T., “,”ASME Journal of Mechanical Design, 40(5), 2018.
Asafuddoula, M., Singh, H. andRay, T., “,”IEEE Transactions on Cybernetics,vol. 48, issue 8, pp. 2321-2334, 2018.
Bhattacharjee, K.S., Singh, H., Ryan, M., and Ray, T., “,”IEEE Transactions on Evolutionary Computation, vol. 21, issue 5, pp. 813-820, 2017.
Branke, J.,Asafuddoula, M., Bhattacharjee, K.S.,Ray, T., “,”IEEE Transactions on Evolutionary Computation, vol. 21, issue 1, pp. 52-64, 2017.
Asafuddoula, M., Ray, T. and Sarker, R., “,” IEEE Transactions on Evolutionary Computation, vol. 19, issue 3, pp. 445-460, 2015.
Singh, H., Ray, T. and Sarker, R., “,” Evolutionary Computation, vol. 21, no. 1, pp. 65-82, 2013.
Mistree, F., W.F. Smith, B. Bras, J.K. Allen, and D. Muster,. Transactions SNAME, 1990. 98: p. 565-597
Research projects
Evolutionary computation for robust multi-objective engineeringdesign
A novel and efficient approach for optimisation involving iterative solvers
Solution of Interest identification based on recursive expected marginal utility
Intelligent Algorithms for Portfolio Selection in Future Force Design
Development of Methods and Algorithms to Support Multidisciplinary Optimisation
Culture
Some members of our team hold prominent roles in international and Australasian conferences such as:
- Institute of Electrical and Electronic Engineers (IEEE) Congress on Evolutionary Computation (CEC)
- Association for Computing Machinery (ACM) Genetic and Evolutionary Computation Conference (GECCO)
- IEEE Solid-State Circuits Society (SSCI)
- Australasian Conference on Artificial Life and Computational Intelligence (ACALCI)
- Intelligent Evolutionary Systems (IES)
- Evolutionary Multi-criteria Optimisation (EMO).
We actively lead and participate in professional activities including IEEE Computational Intelligence Society local chapter, Taskforces, and editorial boards and reviewers for key journals in the field of engineering design and optimisation.
Study with us
PhD projects are available on an ongoing basis in the field of evolutionary computation anddesign optimisation. Utilisingprinciples of optimal design, topics include:
- multi-objectiveoptimisation
- constrainedoptimisation
- bileveloptimisation
- multi-criteriadecision-making
- robustoptimisation
- multi-fidelityoptimisation.
If you are interested in applying for PhD projects on the above topics, please contact
The following course is available to fourth year undergraduate students:
The content covered in this course applies to a diverse range of problems. Students who undertake this course have remarked on the fact that they learnt a new valuable tool, and several have applied their learnings in their final year thesis project.
