This thesis investigates the design of optimization algorithms for solving complex and computationally expensive optimization problems. The thesis focuses on one central question: How can an optimization algorithm be effectively and efficiently designed to solve computationally expensive real-world problems? Therefore, a central aspect of the research is the development of a meta-optimization framework for tuning the parameters of the Covariance Matrix Adaptation Evolution Strategy (CMA-ES). The proposed method involves the generation of surrogate optimization problems that mirror the complexity of the original optimization problem landscapes. Then, the generated surrogate optimization problems are used as tuning references for the meta-optimization. Moreover, a dataset has been created that represents real-world optimization problem instances from the field of vehicle dynamics. This dataset reduces the computational effort associated with complex simulations and enables the efficient design of algorithms.

• benchmarking
• control systems
• exploratory analysis

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