Getting Started

From DFN Wiki
Revision as of 16:35, 23 August 2018 by Martin Cupak (talk) (renamed box -> enclosure)
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to: navigation, search

The DFN observatories use a GNU/Linux operating system (Debian) and can be fully controlled through the Linux terminal either locally or remotely from anywhere in the world. Much of the observatories' functionality is also accessible through a graphical web interface which can also be used locally or remotely.

There is more than one type of DFN observatory; you can figure out what type you have here. Most of the instructions on this wiki will focus primarily on the latest DFNEXT observatories as more of these have been delivered to collaborators than the other types and this is the only fireball observatory design still in production.

Lens and DSLR installation

In order to prevent the issues with lenses being damaged and/or de-focussed in transport, the DSLR body and Samyang lens are shipped separately to the main box. That completely eliminates the mechanical stress transferred from the packaging to the DSLR/lens joint. On the other hand, that means the user will need to install them in the box upon arrival.

Please follow these instructions: How to install flanged Samyang lens and DSLR to the DFNEXT enclosure

Connecting to Your Fireball Observatory for the First Time

DFN camera network interfaces

You will probably want to set your fireball camera up in your lab or office before you install it. This will allow you to try logging in, configuring the camera and running a test in a comfortable environment.

There are three ways to connect to the observatory depending on your situation. These are:

You have the choice of either using the terminal or the graphical web interface for all three of the above connection scenarios. (Although logging in locally using a monitor and keyboard is not recommended if you want to use the web interface.)

Two Options for Controlling Your Observatory: the Terminal and the Web Interface

The Linux terminal is a powerful text based interface that can be used to control the fireball observatories or any other Linux computer. Other operating systems including BSD, Mac OS X, Windows, Android and iOS can also be controlled from a terminal; however, levels of support vary.

If you are only familiar with graphical user interfaces such as the Windows Shell or Mac OS X Aqua it may initially be hard to see the appeal of the terminal, as the command line is a fundamentally different way of interacting with your computer. However, some of the advantages are that:

  • commands can be executed on remote computers as easily as on your local computer (even over poor connections),
  • the interface is a very fast way of getting things done once you know what you're doing,
  • multiple commands can be used together to do quite fancy things and
  • it is easier and less time consuming to create command line interface (CLI) programs than it is to create graphical user interface (GUI) programs.

DFN observatories can be fully controlled through the terminal; however, most functionality (including all common operations) is also now available through the graphical web interface. This interface is useful for users who prefer graphical interfaces, users on mobile devices and for quickly accomplishing small tasks such as turning the drives on and off.

TODO: finish tidying up this page

There are a few things you might want to set up on your local machine to make your life easier:

We currently have three different fireball observatory designs; see Which camera do I have?

In order to check that the camera survived the transport and before deploying, we recommend to do a few basic configurations, then you can run a couple of tests (see Configuring the Software)

Selecting an Appropriate Site for Deployment

An example of bad light pollution. 
An example of low light pollution and a good horizon.

Easy is better than hard, you are not scouting for a site to put the next 10 metre class telescope! However those simple principles help ensure maximum science returns from the cameras:

  • Light Pollution: The amount of light pollution in an area generally depends on its vicinity to towns or cities, and can affect the quality of the night sky images substantially. We recommend taking a look at to assess your proposed area for its level of light pollution. No worse than green as a rule of thumb, but the darker the better.
  • Camera Spacing: If you are installing more than one camera or have existing cameras installed in your area, then you will need to space these units between 80km and 150km apart to optimise both network coverage and triangulability. Spacing in outback Australia is typically 100-150 km, for more light polluted areas 80-100 km is best.
  • Minimise Ocean Coverage: The primary goal of the DFN is to recover meteorites with orbits. This is much harder to accomplish if the meteorite lands in the water. So to make the best use of our camera's coverage, we advise placing the camera unit at least 50km away from the coastline if possible.
  • Reasonably Accessible: Occasionally these camera units need maintenance and servicing to ensure they are fully operational, such as changing the hard-drives and cleaning the lenses. Therefore, we would advise locating it within easy car access. This can include farmland (with owners permission of course) or off-road to avoid interference from car headlights and potential vandalism.
  • Internet connection: the camera boxes come with ethernet ports and WiFi, they don't require a fast internet connection. When land internet is not available or too complicated to organise, the 3G/4G modem can be used with a SIM card, check the coverage of local GSM providers. In Australia see the Telstra coverage map or the Optus coverage map. The GPS/3G external antenna that comes with the camera is usually enough to get a good signal in the light orange areas on the Telstra map ("3G external antenna"), a larger antenna can extend the coverage even further.
  • Horizon Views: Ideally, a location with uninterrupted view of the whole horizon is preferred. This means avoiding areas in valleys, near man-made structures, or with an abundance of trees.
  • Roof versus ground setup: a roof setup seems easy and convenient, but can actually take more time to set up than a ground setup and sometime be an issue regarding health and safety.

Deploying Your Fireball Observatory

Physical Installation

Fireball observatories need to be securely mounted; movement will degrade data quality. They also require reliable power and internet connections.

Rooftop Fireball Camera Installation

Standalone Fireball Camera Installation

Rooftop Kit Camera Installation (if your fireball camera has a clear top and only one lens)

Software Configuration

Configuring the Software

Calibrating the camera orientation

Creating a Mask to remove non-sky regions of the image

Checking Images

Point to downloading images...