Content

Code location

In LCLS software release code of the class RadialBkgd resides in the package pyimgalgos.

Auto-generated documentation for class RadialBkgd

Initialization

from pyimgalgos.RadialBkgd import RadialBkgd
rb = RadialBkgd(xarr, yarr, mask=None, radedges=None, nradbins=100, phiedges=(0,360), nphibins=32)

See parameters description in Auto-generated documentation for class RadialBkgd.

Algorithm

Intention

This algorithm is intended to subtract background from images with quasi-symmetric radial distribution of intensities. For example, water ring background:

To evaluate background in data, n-d array of data is split for 2-d bins in polar coordinate frame, total intensity and number of involved pixels are counted for each bin and converted to the average bin intensity.

Then this averaged intensity is per-pixel subtracted form data n-d array.

Description

Input per-pixel coordinates passed in numpy arrays xarr, yarr are used to evaluate per-pixel radius and polar angle:

rad = rb.pixel_rad()
phi = rb.pixel_phi()

Binning parameters radedges, nradbins, phiedges, nphibins are used to initialize 2-d bins using class HBins. Initialization with default binning parameters covers entire detector coordinate space.

Non-default binning, for example like

rb = RadialBkgd(X, Y, mask, nradbins=3, nphibins=8, phiedges=(-20, 240), radedges=(10000,80000))

defines angular pixel coordinates with correct offset relative to minimal angle,

and gives 3 bins in radial direction from 10mm to 80mm and 8 bins in angle from -20 to 240 degree:

rad = rb.pixel_rad()
iseq = rb.pixel_iseq()

Pixels masked by the n-d array passed in the parameter mask are excluded from this algorithm and are not corrected.

Averaged background intensity for default and non-default binning cases (nphibins=8, nradbins=500):

bkgd = rb.bkgd_nda(nda)

Background subtraction

Background subtracted data for default (nradbins=100, nphibins=32) and non-default binning cases (nradbins=500, nphibins=1), and (nradbins=500, nphibins=8, phiedges=(-20, 240)):

res = rb.subtract_bkgd(nda)

Polarization correction

For good statistical background averaging 2-d bins should contain large number of pixels. Binning artifact in some places are seen in resulting image.
Photon beam polarization effect is observed in the image with single angular bin (ring-shaped radial bins). One could eliminate this effect by modulation of the background sample using polarization correction:

pf = polarization_factor(rb.pixel_rad(), rb.pixel_phi(), z)
res = rb.subtract_bkgd(nda * pf)

For z=1m we get polarization correction factor, corrected data (water-ring) sample, and background subtracted data:

Radial Background Subtraction Algorithm