few more pyFAI related functions includind a neat way to quickly find the center and some utility (pyFAI_dict)

2017-01-04 17:14:35 +01:00 · 2017-01-04 17:14:35 +01:00 · 0a7b628ac1
parent 518fc6175e
commit 0a7b628ac1
1 changed files with 71 additions and 0 deletions
--- a/mcutils.py
+++ b/mcutils.py
@ -1220,6 +1220,24 @@ def insertInSortedArray(a,v):
  a[idx]=v
  return a
 ##### X-ray images #############
 def pyFAIread(fname):
  import fabio
  f = fabio.open(fname)
  data = f.data
  del f
  return data
 def pyFAI_dict(ai):
  """ ai is a pyFAI azimuthal intagrator"""
  methods = dir(ai)
  methods = [m for m in methods if m.find("get_") == 0]
  names   = [m[4:] for m in methods]
  values  = [getattr(ai,m)() for m in methods]
  ret = dict( zip(names,values) )
  return ret
 def pyFAI1d(ai, imgs, mask = None, npt_radial = 600, method = 'csr',safe=True,dark=10., polCorr = 1):
    """ ai is a pyFAI azimuthal intagrator 
              it can be defined with pyFAI.load(ponifile)
@ -1252,6 +1270,59 @@ def pyFAI2d(ai, imgs, mask = None, npt_radial = 600, npt_azim=360,method = 'csr'
      out[_i] = i2d
    return q,azTheta,np.squeeze(out)
 def _calc_R(x,y, xc, yc):
  """ calculate the distance of each 2D points from the center (xc, yc) """
  return np.sqrt((x-xc)**2 + (y-yc)**2)
 def _chi2(c, x, y):
  """ calculate the algebraic distance between the data points and the mean
      circle centered at c=(xc, yc) """
  Ri = _calc_R(x, y, *c)
  return Ri - Ri.mean()
 def leastsq_circle(x,y):
  from scipy import optimize
  # coordinates of the barycenter
  center_estimate = np.nanmean(x), np.nanmean(y)
  center, ier = optimize.leastsq(_chi2, center_estimate, args=(x,y))
  xc, yc = center
  Ri       = _calc_R(x, y, *center)
  R        = Ri.mean()
  residu   = np.sum((Ri - R)**2)
  return xc, yc, R
 def pyFAI_find_center(img,psize=100e-6,dist=0.1,wavelength=0.8e-10,**kwargs):
  import pyFAI
  plt.ion()
  kw = dict( pixel1 = psize, pixel2 = psize, dist = dist,wavelength=wavelength )
  kw.update(kwargs)
  ai =  pyFAI.azimuthalIntegrator.AzimuthalIntegrator(**kw)
  fig_img,ax_img = plt.subplots(1,1)
  fig_pyfai,ax_pyfai = plt.subplots(1,1)
  fig_pyfai = plt.figure(2)
  ax_img.imshow(img)
  plt.sca(ax_img); # set figure to use for mouse interaction
  ans = ""
  print("Enter 'end' when done")
  while ans != "end":
    if ans == "":
      print("Click on beam center:")
      plt.sca(ax_img); # set figure to use for mouse interaction
      xc,yc = plt.ginput()[0]
    else:
      xc,yc = map(float,ans.split(","))
    print("Selected center:",xc,yc)
    ai.set_poni1(xc*psize)
    ai.set_poni2(yc*psize)
    q,az,i = pyFAI2d(ai,img)
    ax_pyfai.pcolormesh(q,az,i)
    ax_pyfai.set_title(str( (xc,yc) ))
    plt.pause(0.01)
    plt.draw()
    ans=input("Enter to continue with clinking or enter xc,yc values")
  print("Final values: (in pixels) %.3f %.3f"%(xc,yc))
  return ai
 ### Objects ###