|Build Status| |Python 3.6+|
Benchopt is a package to simplify and make more transparent and reproducible the comparisons of optimization algorithms. This benchmark is dedicated to the the L1-regularized quantile regression problem:
$$\min_{\beta, \beta0} \frac{1}{n} \sum{i=1}^{n} \text{pinball}(y_i, x_i^\top \beta + \beta_0) + \lambda \lVert \beta \rVert_1$$
where
$$\text{pinball}(y, \hat{y}) = \alpha \max(y - \hat{y}, 0) + (1 - \alpha) \max(\hat{y} - y, 0)$$
where $n$ (or n_samples) stands for the number of samples, $p$ (or n_features) stands for the number of features and
$$X = [x_1^\top, \dots, x_n^\top]^\top \in \mathbb{R}^{n \times p}$$
This benchmark can be run using the following commands:
.. code-block::
$ pip install -U benchopt $ git clone https://github.com/benchopt/benchmark_quantile_regression $ benchopt run benchmark_quantile_regression
Apart from the problem, options can be passed to benchopt run, to restrict the benchmarks to some solvers or datasets, e.g.:
.. code-block::
$ benchopt run benchmark_quantile_regression -s scipy -d simulated --max-runs 10 --n-repetitions 10Use benchopt run -h for more details about these options, or visit https://benchopt.github.io/api.html.
.. |Build Status| image:: https://github.com/benchopt/benchmark_quantile_regression/workflows/Tests/badge.svg :target: https://github.com/benchopt/benchmark_quantile_regression/actions .. |Python 3.6+| image:: https://img.shields.io/badge/python-3.6%2B-blue :target: https://www.python.org/downloads/release/python-360/