Masking Pipeline

CHX Olog NoteBook

CHX Olog (https://logbook.nsls2.bnl.gov/11-ID/)



In [185]:

    
from chxanalys.chx_libs import (np, roi, time, datetime, os,  getpass, db, get_images,LogNorm, plt,ManualMask)
from chxanalys.chx_libs import cmap_albula, cmap_vge, random
from chxanalys.chx_generic_functions import (get_detector, get_meta_data,create_user_folder,
                                             get_fields,  get_sid_filenames,load_data,
                                             RemoveHot, show_img,get_avg_img, 
                                             reverse_updown,create_cross_mask,mask_badpixels )
from skimage.draw import line_aa, line, polygon, circle
 
%matplotlib notebook

Path for Saving Results



In [186]:

    
CYCLE= '2017_3'  #change clycle here



In [187]:

    
path = '/XF11ID/analysis/%s/masks/'%CYCLE
print ("The analysis results will be saved in : %s"%path)









    



The analysis results will be saved in : /XF11ID/analysis/2017_3/masks/

Get the image series and metadata from the uid



In [188]:

    
uid = 'e09db5' # (scan num: 6358) (Measurement: Single image for masking )
uid = '727729' # (scan num: 6708) (Measurement: test series with feedback )
uid =  '2bc66e'# (scan num: 6709) (Measurement: .2s 1k 36/.2% )



In [189]:

    
md = get_meta_data( uid )
detector = get_detector( db[uid ] )
print ('Detector is:  %s'%detector  )
sud = get_sid_filenames(db[uid])

print ('scan_id, full-uid, data path are:  %s--%s--%s'%(sud[0], sud[1], sud[2][0] ))









    



Detector is:  eiger4m_single_image
scan_id, full-uid, data path are:  6709--2bc66efd-57f3-47f8-9b8e-a013972f2e00--/XF11ID/data/2017/09/23/2674253e-b37c-43be-98c7_1495



In [190]:

    
print(md['beam_center_y'], md['beam_center_x'])









    



1218.0 1099.0



In [191]:

    
imgs = load_data( uid, detector, reverse= False  )
#imgs = load_data( uid, detector, reverse= True  )
md.update( imgs.md );Nimg = len(imgs);
#if 'number of images'  not in list(md.keys()):
md['number of images']  = Nimg
pixel_mask =  1- np.int_( np.array( imgs.md['pixel_mask'], dtype= bool)  )
print( 'The data are: %s' %imgs )









    



The data are: <Frames>
Length: 1000 frames
Frame Shape: 2167 x 2070
Pixel Datatype: uint32



In [192]:

    
pixel_mask =  1- np.int_( np.array( md['pixel_mask'], dtype= bool)  )



In [193]:

    
img_choice_N = 1  #can change this number to select more frames for average
img_samp_index = random.sample( range(len(imgs)), img_choice_N) 
avg_img =  get_avg_img( imgs, img_samp_index, plot_ = False, uid = uid)

show image and the pixel mask

show image



In [194]:

    
show_img(  avg_img*pixel_mask , vmin=.001, vmax=1e8, logs=True, 
         image_name ='uid=%s'%uid, aspect=1, cmap= cmap_albula  )

pixel mask

Update Pixel Mask due to bad pixel of Eiger Detector



In [195]:

    
pixel_mask = mask_badpixels( pixel_mask, md['detector'])



In [196]:

    
show_img( pixel_mask, vmin=0, vmax=1, image_name ='pixel_mask--uid=%s'%uid ,aspect=1 )

Remove hotspots in the image



In [197]:

    
#avg_img =  get_avg_img( imgs, sampling = 1000, plot_ = False, uid =uid)



In [198]:

    
mask_rh  = RemoveHot( avg_img, 2**20-1, plot_=True)



In [199]:

    
show_img(avg_img*pixel_mask,vmin=0.1,vmax=1e3, logs=True, 
         image_name= 'uid= %s with pixel mask'%uid , aspect=1, cmap= cmap_albula  )



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Create a polygon mask

check beam center



In [200]:

    
md['beam_center_x'], md['beam_center_y']









    Out[200]:





(1099.0, 1218.0)

To create multi-rectangle masks, for each sub-mask



In [201]:

    
path









    Out[201]:





'/XF11ID/analysis/2017_3/masks/'



In [202]:

    
#creat the right part mask
partial_mask = create_cross_mask(  avg_img,center=[1000,1218],
                            wy_left= 0, wy_right= 35, 
                              wx_up= 0, wx_down= 0,center_radius= 0 )



In [203]:

    
show_img(  partial_mask   )



In [204]:

    
#np.save( '/XF11ID/analysis/2017_1/masks/Ver_Beamstop', partial_mask )
#Ver_Beamstop = np.load( '/XF11ID/analysis/2017_1/masks/Ver_Beamstop.npy' )
#Ver_Beamstop = move_beamstop( Vertical_Beamstop, xshift=0, yshift=0 )



In [205]:

    
#creat the left/right/up/down part mask
partial_mask *=  create_cross_mask(  avg_img, center=[ 1099,1218],
                            wy_left= 0, wy_right= 0, 
                              wx_up= 5, wx_down=5,center_radius= 0 )
#partial_mask2[1285:1350,1430:1440,] = False



In [206]:

    
#creat the left/right/up/down part mask
partial_mask *=  create_cross_mask(  avg_img, center=[ 1030,395],
                            wy_left= 145, wy_right= 0, 
                              wx_up= 0, wx_down= 0,center_radius= 0 )
#partial_mask2[1285:1350,1430:1440,] = False



In [207]:

    
#creat the left/right/up/down part mask
partial_mask *=  create_cross_mask(  avg_img, center=[ 1139,1225],
                            wy_left= 0, wy_right= 0, 
                              wx_up= 0, wx_down=0,center_radius= 0 )
#partial_mask2[1285:1350,1430:1440,] = False



In [208]:

    
#from chxanalys.chx_generic_functions import create_multi_rotated_rectangle_mask



In [ ]:



In [209]:

    
#np.save( '/XF11ID/analysis/2017_1/masks/Hor_Beamstop', partial_mask )
#Hor_Beamstop = np.load( '/XF11ID/analysis/2017_1/masks/Hor_Beamstop.npy' )
#Hor_Beamstop = move_beamstop( Hor_Beamstop, xshift=0, yshift=0 )



In [210]:

    
show_img(  partial_mask   )



In [211]:

    
#creat the left/right/up/down part mask
#partial_mask *=  create_cross_mask(  avg_img, center=[ 1615,2000],
#                            wy_left= 0, wy_right= 100, 
#                              wx_up= 0, wx_down=0,center_radius= 0 )
#partial_mask2[1285:1350,1430:1440,] = False



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In [212]:

    
#np.save( '/XF11ID/analysis/2017_1/masks/Bad_4M', partial_mask )
#Bad_4M = np.load( '/XF11ID/analysis/2017_1/masks/Bad_4M.npy' )



In [213]:

    
#create a circle mask for windows
if False: #make it True to make window mask
    window_shadow  = ~create_cross_mask(  avg_img, center=[ 911,997],
                           wy_left= 0, wy_right= 0, 
                             wx_up= 0, wx_down= 0,center_circle=True, center_radius= 680)
else:
    window_shadow = 1



In [214]:

    
full_mask = partial_mask *window_shadow
#full_mask = Ver_Beamstop * Hor_Beamstop *Bad_4M *window_shadow



In [ ]:



In [215]:

    
show_img( full_mask, aspect = 1 )



In [216]:

    
mask = np.array ( full_mask * pixel_mask*mask_rh  , dtype = bool )
#mask = np.array ( full_mask * pixel_mask , dtype = bool )



In [217]:

    
fig, ax = plt.subplots()
#new_mask = 
im=ax.imshow(   (~mask) * avg_img,origin='lower' , 
      norm= LogNorm( vmin=0.001, vmax= 1e5), cmap= cmap_albula)
#im = ax.imshow(avg_img,  cmap='viridis',origin='lower', norm= LogNorm( vmin=0.001, vmax=100 ) )
plt.show()



In [218]:

    
fig, ax = plt.subplots()
im = ax.imshow((mask)*avg_img,  cmap= cmap_albula,origin='lower',norm= LogNorm( vmin=.1, vmax=1e5 ),
               interpolation='none')
plt.show()

Combine the hand-drawn/polygon mask and the pixel mask and hot pixel mask



In [219]:

    
#mask = np.array ( ~new_mask* ~plgon_mask * md['pixel_mask']*mask_rh, dtype = bool )

fig, ax = plt.subplots()
im=ax.imshow(mask, origin='lower' ,vmin=0, vmax=1,cmap='viridis')
fig.colorbar(im)
plt.show()

Save the combined mask to use in further data analysis



In [222]:

    
np.save(  path +   uid +"_mask", mask)



In [223]:

    
path +   uid +"_mask"









    Out[223]:





'/XF11ID/analysis/2017_3/masks/2bc66e_mask'

save with a meaningful filename, make False after excute to avoid overwrite



In [224]:

    
if True:
    meaningful_name = 'Sept23_SAXS' 
    np.save(  path +   meaningful_name, mask)
    print( path +   meaningful_name )









    



/XF11ID/analysis/2017_3/masks/Sept23_SAXS



In [225]:

    
path +   meaningful_name









    Out[225]:





'/XF11ID/analysis/2017_3/masks/Sept23_SAXS'



In [226]:

    
2ef764uid









    Out[226]:





'2bc66e'



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