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Deep-ELA: Deep Exploratory Landscape Analysis with Self-Supervised Pretrained Transformers for Single-Objective and

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  • 1Machine Learning and Optimisation, Paderborn University, Germany moritz.seiler@uni-paderborn.de.

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Summary
This summary is machine-generated.

This study introduces Deep-ELA, a hybrid approach combining deep learning and Exploratory Landscape Analysis (ELA) features. Deep-ELA effectively characterizes optimization problem landscapes for improved analysis and algorithm selection.

Keywords:
Deep learningautomated algorithm selectionexploratory landscape analysishigh-level property predictionmultiobjective optimizationsingle-objective optimization

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Area of Science:

  • Artificial Intelligence
  • Optimization
  • Machine Learning

Background:

  • Exploratory Landscape Analysis (ELA) features numerically characterize single-objective optimization problems.
  • ELA features are crucial for machine learning tasks like algorithm selection but have drawbacks such as feature correlation and limited applicability to multiobjective problems.
  • Deep learning approaches have been proposed as alternatives but require substantial labeled data.

Purpose of the Study:

  • To propose a hybrid approach, Deep-ELA, that combines the strengths of deep learning and ELA features.
  • To develop a method for characterizing both single- and multiobjective continuous optimization problems.
  • To create a framework that can be used out-of-the-box or fine-tuned for specific tasks.

Main Methods:

  • Pre-training four transformers on millions of randomly generated optimization problems.
  • Learning deep representations of continuous optimization problem landscapes.
  • Developing a hybrid deep learning and ELA framework.

Main Results:

  • Deep-ELA effectively learns deep representations of optimization landscapes.
  • The framework demonstrates applicability to both single- and multiobjective continuous optimization problems.
  • The approach addresses limitations of traditional ELA features and data-hungry deep learning methods.

Conclusions:

  • Deep-ELA offers a powerful, flexible framework for analyzing and understanding continuous optimization problems.
  • The hybrid approach enhances the characterization of optimization landscapes, benefiting algorithm selection and configuration.
  • This work paves the way for more advanced analysis of complex optimization tasks.