Re-Examining Linear Embeddings for High-Dimensional Bayesian Optimization
About
Bayesian optimization (BO) is a popular approach to optimize expensive-to-evaluate black-box functions. A significant challenge in BO is to scale to high-dimensional parameter spaces while retaining sample efficiency. A solution considered in existing literature is to embed the high-dimensional space in a lower-dimensional manifold, often via a random linear embedding. In this paper, we identify several crucial issues and misconceptions about the use of linear embeddings for BO. We study the properties of linear embeddings from the literature and show that some of the design choices in current approaches adversely impact their performance. We show empirically that properly addressing these issues significantly improves the efficacy of linear embeddings for BO on a range of problems, including learning a gait policy for robot locomotion.
Related benchmarks
| Task | Dataset | Result | Rank | |
|---|---|---|---|---|
| High-dimensional optimization | MSLR | Convergence Value-8.862 | 21 | |
| High-dimensional optimization | LIMO | Convergence Value-7.5033 | 20 | |
| High-dimensional optimization | Lasso-Hard | Convergence Value11.273 | 20 | |
| Function Optimization | Dixon D=1000 | Convergence Value1.09e+5 | 19 | |
| Function Optimization | Michalewicz D=1000 | Convergence Value-8.8393 | 19 | |
| Function Optimization | Sphere D=1000 | Final Value31.3825 | 19 | |
| Function Optimization | Rosenbrock D=1000 | Convergence Value1.10e+5 | 19 | |
| Function Optimization | Griewank D=1000 | Convergence Value (Statistic)18.1015 | 19 | |
| Function Optimization | Levy D=1000 | Convergence Value35.0879 | 19 | |
| Black-box Optimization | Hartmann-6D 300 evaluations | Wall Clock Time (s)470.7 | 10 |