AstroML: Machine Learning for Astronomy
AstroML is a Python module for machine learning and data mining built on numpy, scipy, scikit-learn, and matplotlib, and distributed under the BSD license. It contains a growing library of statistical and machine learning routines for analyzing astronomical data in python, loaders for several open astronomical datasets, and a large suite of examples of analyzing and visualizing astronomical datasets.
This project was started in 2012 by Jake VanderPlas to accompany the book Statistics, Data Mining, and Machine Learning in Astronomy by Zeljko Ivezic, Andrew Connolly, Jacob VanderPlas, and Alex Gray.
Core and Addons
The project is split into two components. The core astroML
library is
written in python only, and is designed to be very easy to install for
any users, even those who don't have a working C or fortran compiler.
A companion library, astroML_addons
, can be optionally installed for
increased performance on certain algorithms. Every algorithm
in astroML_addons
has a pure python counterpart in the
core astroML
implementation, but the astroML_addons
library
contains faster and more efficient implementations in compiled code.
Furthermore, if astroML_addons
is installed on your system, the core
astroML
library will import and use the faster routines by default.
The reason for this split is the ease of use for newcomers to Python. If the
prerequisites are already installed on your system, the core astroML
library can be installed and used on any system with little trouble. The
astroML_addons
library requires a C compiler, but is also designed to be
easy to install for more advanced users. See further discussion in
"Development", below.
Important Links
- HTML documentation: http://www.astroML.org
- Core source-code repository: http://github.com/astroML/astroML
- Addons source-code repository: http://github.com/astroML/astroML_addons
- Issue Tracker: http://github.com/astroML/astroML/issues
- Mailing List: https://groups.google.com/forum/#!forum/astroml-general
Installation
This package uses distutils, which is the default way of installing python modules. Before installation, make sure your system meets the prerequisites listed in Dependencies, listed below.
Core
To install the core astroML
package in your home directory, use:
pip install astroML
The core package is pure python, so installation should be straightforward on most systems. To install from source, use:
python setup.py install
You can specify an arbitrary directory for installation using:
python setup.py install --prefix='/some/path'
To install system-wide on Linux/Unix systems:
python setup.py build sudo python setup.py install
Addons
The astroML_addons
package requires a working C/C++ compiler for
installation. It can be installed using:
pip install astroML_addons
To install from source, refer to http://github.com/astroML/astroML_addons
Dependencies
There are three levels of dependencies in astroML. Core dependencies are
required for the core astroML
package. Add-on dependencies are required
for the performance astroML_addons
. Optional dependencies are required
to run some (but not all) of the example scripts. Individual example scripts
will list their optional dependencies at the top of the file.
Core Dependencies
The core astroML
package requires the following:
- Python version 2.6-2.7 and 3.3+
- Numpy >= 1.4
- Scipy >= 0.7
- Scikit-learn >= 0.10
- Matplotlib >= 0.99
- AstroPy > 0.2.5 AstroPy is required to read Flexible Image Transport System (FITS) files, which are used by several datasets.
This configuration matches the Ubuntu 10.04 LTS release from April 2010, with the addition of scikit-learn.
To run unit tests, you will also need nose >= 0.10
Add-on Dependencies
The fast code in astroML_addons
requires a working C/C++ compiler.
Optional Dependencies
Several of the example scripts require specialized or upgraded packages. These requirements are listed at the top of the particular scripts
- Scipy version 0.11 added a sparse graph submodule. The minimum spanning tree example requires scipy >= 0.11
- PyMC provides a nice interface for Markov-Chain Monte Carlo. Several astroML examples use pyMC for exploration of high-dimensional spaces. The examples were written with pymc version 2.2
- HEALPy provides an interface to the HEALPix pixelization scheme, as well as fast spherical harmonic transforms.
Development
This package is designed to be a repository for well-written astronomy code, and submissions of new routines are encouraged. After installing the version-control system Git, you can check out the latest sources from GitHub using:
git clone git://github.com/astroML/astroML.git
or if you have write privileges:
git clone git@github.com:astroML/astroML.git
Contribution
We strongly encourage contributions of useful astronomy-related code: for astroML to be a relevant tool for the python/astronomy community, it will need to grow with the field of research. There are a few guidelines for contribution:
General
Any contribution should be done through the github pull request system (for
more information, see the
help page
Code submitted to astroML
should conform to a BSD-style license,
and follow the PEP8 style guide.
Documentation and Examples
All submitted code should be documented following the Numpy Documentation Guide. This is a unified documentation style used by many packages in the scipy universe.
In addition, it is highly recommended to create example scripts that show the
usefulness of the method on an astronomical dataset (preferably making use
of the loaders in astroML.datasets
). These example scripts are in the
examples
subdirectory of the main source repository.
Add-on code
We made the decision early-on to separate the core routines from high-performance compiled routines. This is to make sure that installation of the core package is as straightforward as possible (i.e. not requiring a C compiler).
Contributions of efficient compiled code to astroML_addons
is encouraged:
the availability of efficient implementations of common algorithms in python
is one of the strongest features of the python universe. The preferred
method of wrapping compiled libraries is to use
cython; other options (weave, SWIG, etc.) are
harder to build and maintain.
Currently, the policy is that any efficient algorithm included in
astroML_addons
should have a duplicate python-only implementation in
astroML
, with code that selects the faster routine if it's available.
(For an example of how this works, see the definition of the lomb_scargle
function in astroML/periodogram.py
).
This policy exists for a few reasons:
- it allows novice users to have all the functionality of
astroML
without requiring the headache of complicated installation steps. - it serves a didactic purpose: python-only implementations are often easier to read and understand than equivalent implementations in C or cython.
- it enforces the good coding practice of avoiding premature optimization. First make sure the code works (i.e. write it in simple python). Then create an optimized version in the addons.
If this policy proves especially burdensome in the future, it may be revisited.
Authors
Package Author
- Jake Vanderplas <vanderplas@astro.washington.edu> http://jakevdp.github.com
Code Contribution
- Morgan Fouesneau https://github.com/mfouesneau
- Julian Taylor http://github.com/juliantaylor