| Welcome, Space Apps challengers, to �Seismic Detection across the Solar System�. | |
| Today, we challenge YOU to parse through seismic data collected on the Moon and Mars and figure out how to detect moonquakes and marsquakes! | |
| To get you started on the data, we present to you a training set containing the following: | |
| 1. A catalog of quakes identified in the data | |
| 2. Seismic data collected by the Apollo (one day segments) or InSight (one hour segments) missions in miniseed and CSV format. | |
| 3. Plots of the trace and spectrogram for each day a quake has been identified. | |
| Using these tools, your task is to come up with an algorithm to identify these signals (using the catalog as a benchmark) and then | |
| apply your algorithm to the seismic data in the "test" folder (Apollo 12, 15, and 16 for the Moon and other InSight events for Mars). | |
| Each trace included in the test folder has a quake in it, there are no empty traces. | |
| This main folder also has a Jupyter notebook that will help you get started on the data. | |
| ** IMPORTANT ** | |
| Please make sure that your output catalog has at least the following headers: | |
| filename | |
| time_abs(%Y-%m-%dT%H:%M:%S.%f) or time_rel(sec) | |
| If not, your output catalog may not be scored!! | |
| ** IMPORTANT ** | |
| Good luck!!! If you have any questions, our team leaders will be around to help during the hackathon weekend! |