By clicking on the red folder icon in the top left
By selecting the Open Data Set item under the File menu or using the
equivalent shortcut (e.g. Ctrl+O on Linux, Cmd+O on Mac).
By dragging and dropping data files onto the main window
Find and open the file w5.fits which should be in the w5.tgz or
w5.zip archive you downloaded above. This is a WISE image of the W5 Star Forming Region. While this is an astronomical
dataset, glue can be used for data in any discipline, and many of the concepts
shown below are applicable to many types of dataset.
After opening w5.fits, a new entry will appear in the data manager:
To visualize a dataset, click and drag the entry from the data manager to the
visualization dashboard. A popup window asks about what kind of plot to make.
Since this is an image, select 2D Image Viewer.
Work in glue revolves around “drilling down” into interesting subsets within
data. Each visualization type (image, scatterplot, …) provides different ways
for defining these subsets. In particular, the image window provides 5 options:
To use these, click on one of the selection icons then click and drag on the
image to define a selection. If using the polygon selection, you should press
‘enter’ when the selection is complete (or ‘escape’ to cancel).
We can highlight the west arm of W5 using the rectangle selector:
Notice that this highlights the relevant pixels in the image, adds a new subset
(named Subset 1) to the data manager, and adds a new visualization layer in
the visualization dashboard.
We can redefine this subset by dragging a new rectangle in the image, or we can
also move around the current subset by pressing the ‘control’ key and clicking
on the subset then dragging it. As long as Subset 1 is selected in the data
collection view in the top left, drawing selections will redefine Subset 1.
If you deselect this subset and draw a new region, a new subset will be
You can edit the properties of a visualization layer (color, transparency, etc.)
by clicking on the layer in the Plot layers list on the left. Likewise, you
can re-arrange the rows in this widget to change the order in which each layer
is drawn – the top entry will appear above all other entries.
Visualizations are linked in Glue – that is, we can plot this data in many
different ways, to better understand the properties of each subset. To see this,
click and drag the W5[PRIMARY] entry into the visualization area a second
time, and make a histogram. Edit the settings in the histogram visualization
dashboard to produce something similar to this:
This shows the distribution of intensities for the image as a whole (gray), and
for the subset in red (the label PRIMARY comes from the FITS header)
Perhaps we wish to remove faint pixels from our selection. To do this, we pick
the last mode (Remove From Selection) from the selection mode toolbar:
When this mode is active, new regions defined by the mouse are subtracted from
the selected subsets. We can therefore highlight the region between x=450-500 in
the histogram to remove this region from the data.
Make sure you switch back to the first, default selection mode
(Replace Selection) once you have finished defining the
Glue is designed so that visualization and drilldown can span multiple datasets.
To do this, we need to inform Glue about the logical connections that exist
between each dataset.
Open the second file, w5_psc.vot – a catalog of Spitzer-identified point
sources towards this region. You will see a new entry in the data manager. We
can double click on that entry to rename it to Point Sources, and the result
will look like this:
At this point, you can visualize and drilldown into this catalog. However, Glue
doesn’t know enough to compare the catalog and image. To do that, we must
Link these two data entries. Click on the LinkData button in the toolbar.
This brings up a new window, showing all the pieces of information within each
Select the two datasets in the network diagram in the top panel, or from the
drop-down menus underneath. The image has an attribute Right Ascension. This
is the same quantity as the RAJ2000 attribute in the Point Sources
dataset – they are both describing Right Ascension (the horizontal spatial
coordinate on the sky). Select these entries, and click Glue to instruct the
program that these quantities are equivalent. Likewise, link Declination and
DEJ2000 (Declination, the other coordinate). Click OK.
What does this do? This tells Glue how to derive the catalog-defined
quantities DEJ2000 and RAJ2000 using data from the image, and
vice versa. In this case, the derivation is simple (it aliases the
quantity Declination or Right Ascension). In general, the
derivation can be more complex (i.e. an arbitrary function that maps
quantities in the image to a quantity in the catalog). Glue uses this
information to apply subset definitions to different data sets,
overplot multiple datasets, etc.
After these connections are defined, subsets that are defined via spatial
constraints in the image can be used to filter rows in the catalog. Let’s see
how that works.
First, make a scatter plot of the point source catalog. Then, select Subset
1 and draw a new region on the image. You should see this selection applied to
You can also overplot the catalog rows on top of the image. To do this, click
the arrow next to the new subset – this shows the individual selections applied
to each dataset. Click and drag the subset for the point source catalog on top
of the image. To see these points more easily, you may want to disable the
layer showing all the points (named Point Sources) in the list of plot
Glue is able to apply this filter to both datasets because it has enough
information to apply the spatial constraint in the image (fundamentally, a
constraint on Right Ascension and Declination) to a constraint in the
catalog (since it could derive those quantities from the RAJ2000 and
Glue stores subsets as sets of constraints – tracing a rectangle
subset on a plot defines a set of constraints on the
quantities plotted on the x and y axes (left < x < right, bottom <
y < top). Copying a subset copies this definition, and pasting it
applies the definition to a different subset.
As was mentioned above, the highlighted subsets in the data manager are the ones
which are affected by selecting regions in the plots. Thus, instead of manually
copy-pasting subsets from the image to the catalog, you can also highlight both
subsets before selecting a plot region. This will update both subsets to match
Careful readers will notice that we didn’t use the image subset
from earlier sections when working with the catalog. This is because
that selection combined spatial constraints (the original rectangle in
the image) with a constraint on intensity (the histogram selection).
There is no mapping from image intensity to quantities in the catalog,
so it isn’t possible to filter the catalog on that subset. In
situations where Glue is unable to apply a filter to a dataset, it
doesn’t render the subset in the visualization.
Glue provides a number of ways to save your work, and to export your work for
further analysis in other programs.
Saving The Session
You can save a Glue session for later work via the Save Session button in
the toolbar or in the File menu. This creates a glue session file (the
preferred file extension is .glu). You can restore this session later via
the Open Session button in the toolbar or in the File menu.
By default, these files store references to the files you opened, and not
copies of the files themselves. Thus, you won’t be able to re-load this
session if you move any of the original data. To include the data in the
session file, you can select ‘Glue Session including data’ when saving:
Static images of individual visualizations can be saved by clicking the floppy
disk icon on a given visualization window. There are also exporters available
under the File menu - built-in exporters include one to export plots to the
plotly service, and one to export plots using
Glue is primarily an exploration environment – eventually, you may want to
export subsets for further analysis. Glue currently supports saving subsets as
FITS masks. Right click on the subset in the data manager (note that you need to
select the subset applied to a specific dataset, not the overall subset, so be
sure to expand the subset by clicking on the triangle on the left of the subset
name), and select Export subset values or Export subset mask(s) to write
the subset to disk.