Region Of Interest (ROI)#

ROIs can be defined to select part of any compatible signal and may be applied either to the navigation or to the signal axes. A number of different ROIs are available:

Once created, an ROI can be applied to the signal:

>>> s = hs.signals.Signal1D(np.arange(2000).reshape((20,10,10)))
>>> im = hs.signals.Signal2D(np.arange(100).reshape((10,10)))
>>> roi = hs.roi.RectangularROI(left=3, right=7, top=2, bottom=5)
>>> sr = roi(s)
>>> sr
<Signal1D, title: , dimensions: (4, 3|10)>
>>> imr = roi(im)
>>> imr
<Signal2D, title: , dimensions: (|4, 3)>

ROIs can also be used interactively with widgets. The following example shows how to interactively apply ROIs to an image. Note that it is necessary to plot the signal onto which the widgets will be added before calling interactive().

>>> import scipy
>>> im = hs.signals.Signal2D(scipy.datasets.ascent())
>>> rectangular_roi = hs.roi.RectangularROI(left=30, right=500,
...                                         top=200, bottom=400)
>>> line_roi = hs.roi.Line2DROI(0, 0, 512, 512, 1)
>>> point_roi = hs.roi.Point2DROI(256, 256)
>>> im.plot()
>>> roi2D = rectangular_roi.interactive(im, color="blue")
>>> roi1D = line_roi.interactive(im, color="yellow")
>>> roi0D = point_roi.interactive(im, color="red")
../_images/image_with_rois.png
../_images/roi1d.png
../_images/roi2d.png

Note

Depending on your screen and display settings, it can be difficult to pick or manipulate widgets and you can try to change the pick tolerance in the HyperSpy plot preferences. Typically, using a 4K resolution with a small scaling factor (<150 %), setting the pick tolerance to 15 instead of 7.5 makes the widgets easier to manipulate.

If instantiated without arguments, (i.e. rect = RectangularROI() the roi will automatically determine sensible values to center it when interactively adding it to a signal. This provides a conventient starting point to further manipulate the ROI, either by hand or using the gui (i.e. rect.gui).

Notably, since ROIs are independent from the signals they sub-select, the widget can be plotted on a different signal altogether.

>>> import scipy
>>> im = hs.signals.Signal2D(scipy.datasets.ascent())
>>> s = hs.signals.Signal1D(np.random.rand(512, 512, 512))
>>> roi = hs.roi.RectangularROI(left=30, right=77, top=20, bottom=50)
>>> s.plot() # plot signal to have where to display the widget
>>> imr = roi.interactive(im, navigation_signal=s, color="red")
>>> roi(im).plot()

ROIs are implemented in terms of physical coordinates and not pixels, so with proper calibration will always point to the same region.

../_images/random_image_with_rect_roi.png
../_images/random_image_with_rect_roi_spectrum.png
../_images/roi2d.png

And of course, as all interactive operations, interactive ROIs are chainable. The following example shows how to display interactively the histogram of a rectangular ROI. Notice how we customise the default event connections in order to increase responsiveness.

>>> import scipy
>>> im = hs.signals.Signal2D(scipy.datasets.ascent())
>>> im.plot()
>>> roi = hs.roi.RectangularROI(left=30, right=500, top=200, bottom=400)
>>> im_roi = roi.interactive(im, color="red")
>>> roi_hist = hs.interactive(im_roi.get_histogram,
...                           event=roi.events.changed,
...                           bins=150, # Set number of bins for `get_histogram`
...                           recompute_out_event=None)
>>> roi_hist.plot()
../_images/image_with_rect_roi.gif

New in version 1.3: ROIs can be used in place of slices when indexing and to define a signal range in functions taken a signal_range argument.

All ROIs have a gui method that displays an user interface if a hyperspy GUI is installed (currently only works with the hyperspy_gui_ipywidgets GUI), enabling precise control of the ROI parameters:

>>> # continuing from above:
>>> roi.gui() 
../_images/roi_gui_control.gif

New in version 1.4: angle() can be used to calculate an angle between ROI line and one of the axes providing its name through optional argument axis:

>>> import scipy
>>> ima = hs.signals.Signal2D(scipy.datasets.ascent())
>>> roi = hs.roi.Line2DROI(x1=144, y1=240, x2=306, y2=178, linewidth=0)
>>> ima.plot()
>>> roi.interactive(ima, color='red')
<BaseSignal, title: , dimensions: (|175)>
../_images/roi_line2d.png
>>> roi.angle(axis='vertical')
110.94265054998827

The default output of the method is in degrees, though radians can be selected as follows:

>>> roi.angle(axis='vertical', units='radians')
1.9363145329867932

Conveniently, angle() can be used to rotate an image to align selected features with respect to vertical or horizontal axis:

>>> ima.map(scipy.ndimage.rotate, angle=roi.angle(axis='horizontal'), inplace=False).plot()
../_images/roi_line2d_rotate.png

Slicing using ROIs#

ROIs can be used in place of slices when indexing. For example:

>>> s = hs.data.two_gaussians()
>>> roi = hs.roi.SpanROI(left=5, right=15)
>>> sc = s.isig[roi]
>>> im = hs.signals.Signal2D(scipy.datasets.ascent())
>>> roi = hs.roi.RectangularROI(left=120, right=460., top=300, bottom=560)
>>> imc = im.isig[roi]

New in version 1.3: gui method added, for example gui().

New in version 1.6: New __getitem__ method for all ROIs.

In addition, all ROIs have a __getitem__ method that enables using them in place of tuples. For example, the method align2D() takes a roi argument with the left, right, top, bottom coordinates of the ROI. Handily, we can pass a RectangularROI ROI instead.

>>> import hyperspy.api as hs
>>> import numpy as np
>>> im = hs.signals.Signal2D(np.random.random((10,30,30)))
>>> roi = hs.roi.RectangularROI(left=2, right=10, top=0, bottom=5)
>>> tuple(roi)
(2.0, 10.0, 0.0, 5.0)
>>> im.align2D(roi=roi) 

Interactively Slicing Signal Dimensions#

plot_roi_map() is a function that allows you to interactively visualize the spatial variation of intensity in a Signal within a ROI of its signal axes. In other words, it shows maps of the integrated signal for custom ranges along the signal axis.

To allow selection of the signal ROIs, a plot of the mean signal over all spatial positions is generated. Interactive ROIs can then be adjusted to the desired regions within this plot.

For each ROI, a plot reflecting how the intensity of signal within this ROI varies over the spatial dimensions of the Signal object is also plotted.

For Signal objects with 1 signal dimension SpanROIs are used and for 2 signal dimensions, RectangularROIs are used.

In the example below, for a hyperspectral map with 2 navigation dimensions and 1 signal dimension (i.e. a spectrum at each position in a 2D map), SpanROIs are used to select spectral regions of interest. For each spectral region of interest a plot is generated displaying the intensity within this region at each position in the map.

>>> import hyperpsy.api as hs 
>>> sig = hs.load('mydata.sur') 
>>> sig 
<Signal1D, dimensions: (128, 128|1024)>
>>> hs.plot.plot_roi_map(sig, rois=2) 
Demo of plot_roi_map functionality.