Skip to content

Exoplanet Transit Detection using Deep Neural Networks written in Python

License

Notifications You must be signed in to change notification settings

dinismf/exoplanet_classification_thesis

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

40 Commits
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

Exoplanet Transit Detection using Deep Neural Networks

MSc dissertation project that focuses on the use of deep neural networks for the detection of exoplanets in solar systems other than our own in the Milky Way. Two deep learning architectures, convolutional (CNN) and long-short term memory (LSTM), are presented as automated vetting methods for the accurate detection of exoplanets in data produced by NASA's Kepler telescope survey.

The networks were optimized to recognise light curve patterns in the photometric time-series data to solve a binary classification task, i.e to determine whether a transit signal is indeed caused by a real transiting planet, or a false positive such as an eclipsing binary star, stellar variability or instrumental artefacts. The final model configurations were able to correctly classify Kepler Threshold-Crossing Events (TCEs) with a recall score of ≈ 93.5%.

In the future, automated vetting procedures like the methods proposed in this research will be commonplace in the Astronomy domain due to the large influx of data from new telescope surveys with the goal of observing celestial objects including exoplanets and many other phenomena in the universe.

Kepler Data Overview

Labelled data from the Q1-Q17 Data Release 24 catalogue was retrieved from the NASA Exoplanet Archive. The DR24 catalogue is composed of ≈ 15740 Threshold-Crossing Events (TCEs).

A sample from the TCE table contains the following attributes:

  • rowid: Integer ID of the row in the TCE table.
  • kepid: Kepler ID of the target star.
  • tce_plnt_num: TCE number within the target star.
  • tce_period: Period of the detected event, in days.
  • tce_time0bk: The time corresponding to the center of the first detected event in Barycentric Julian Day (BJD) minus a constant offset of 2,454,833.0 days.
  • tce_duration: Duration of the detected event, in hours.
  • av_training_set: Autovetter training set label; one of PC (planet candidate), AFP (astrophysical false positive), NTP (non-transiting phenomenon), UNK (unknown).

A TCE is any transit-like event that crosses a predefined threshold degree of certainty, which is then subjected to further analysis by the Kepler team to determine if the transit is caused by an exoplanet or other celestial objects/phenomena.

An illustration of an exoplanet transit is shown below.

To get a more in depth understanding of the work behind this project, consult my MSc dissertation here and the papers in the credits section below.

For a shorter summary, a powerpoint presentation was also prepared -> link

Projectpan

Dependencies

Structure


├── LICENSE
├── Makefile           <- Makefile with commands like `make data` or `make train`
├── README.md          <- The top-level README for developers using this project.
├── data
│   ├── processed      <- The final, canonical data sets for modeling.
│   ├── split          <- The train/test split of the processed data. 
│   └── raw            <- The original, immutable data dump.
│
├── models             <- Trained and serialized models, model predictions, or model summaries
│
├── references         <- Data dictionaries, manuals, and all other explanatory materials.
│
├── reports            <- Generated analysis as HTML, PDF, LaTeX, etc.
│   └── figures        <- Generated graphics and figures to be used in reporting
│
├── requirements.txt   <- The requirements file for reproducing the analysis environment, e.g.
│                         generated with `pip freeze > requirements.txt`
│
├── src                <- Source code for use in this project.
    ├── __init__.py    <- Makes src a Python module
    │
    ├── data           <- Scripts to download or generate data
    │   └── make_dataset.py
    │
    ├── helpers
    │   | 
    |   ├──────── thirdparty  <- Third party helper classes for preprocessing light curves 
    |   ├── import_helpers.py
    |   └── train_helpers.py 
    |
    ├── models         <- Scripts to train models and predict new data.
    │   │
    |   ├── model.py
    |   ├── optimize.py
    |   ├── predict_model.py
    │   └── train_model.py
    │
    └── visualization  <- Scripts to create exploratory and results oriented visualizations
        └── visualize.py

<p><small>Project based on the <a target="_blank" href="https://drivendata.github.io/cookiecutter-data-science/">cookiecutter data science project template</a>. #cookiecutterdatascience</small></p>

File Guide

make_dataset.py - Reads Kepler light curves from .fits files

Walkthrough (To Complete)

Setup

Download Kepler Data

Process Kepler Data

Train Models

Predict

Improvements

Credits

Shallue, C. J., & Vanderburg, A. (2018). Identifying Exoplanets with Deep Learning: A Five-planet Resonant Chain around Kepler-80 and an Eighth Planet around Kepler-90. The Astronomical Journal, 155(2), 94. The Astronomical Journal.

K. A. Pearson, L. Palafox, and C. A. Griffith (2017). Searching for Exoplanets using Artificial Intelligence. 15(October):1–15, 2017.Arxiv

Releases

No releases published

Packages

No packages published