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Bright and Dark reference images » History » Version 18

Anchi Cheng, 06/06/2012 07:16 PM

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h1. Bright and Dark reference images
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Bright and Dark reference images need to be acquired for every camera setting that will
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be used. The camera settings include image dimension, bin size, and offset. Over time,
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references may need to be repeatedly acquired.
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h2. Correction Channels
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When two flat-field-corrected images are correlated, there is often an origin peak
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derived from the common normalization image even if both image acquisition contains only
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noise. In order to avoid this problem, two or more sets of bright/dark references, and hence
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normalization images can be obtained per camera configuration. When a correlation
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between two images are done, Leginon will check the channel of the correction the first
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acquired image has used and then force the new image to be corrected by a different
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channel.
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We recommend that you always acquire reference images on both channels.
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h2. Acquire reference images
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#  scope> make sure that the digital camera will be acquiring images in an area with uniform
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beam intensity such as an empty area with no specimen nor support. You may skip a trip
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to the scope room by sending one of the high mag preset to the scope from
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Leginon.
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#  Leginon/Node Selector> Select "Correction" node.
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#  Leginon/Correction/Toolbar> Open "Settings" window.
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#  Leginon/Correction/Toolbar/Settings> Select one of the Common Camera
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Configuration or select Custom mode and enter your own values based on the presets you
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created.
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#  Leginon/Correction/Settings/Camera Configuration> Enter the Exposure time. It
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should be chosen so that the image is not saturated and ideally close to the condition
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that will be used in the experiments. If unsure about the experimental condition, use an
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exposure time that gives high but not saturated counts.
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#  Leginon/Correction/Settings>By default, the corrector node is set to average 3
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images together to create one reference image and to despike the hot pixels with
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averaged neighbor hood values. These can be changed if desired.
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#  Leginon/Correction/Settings> Click OK to exit settings.
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#  Leginon/Correction/Toolbar> Select "Channel 0" in the channel number
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selector so that the next step will acquire only one image.
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#  Leginon/Correction/Toolbar> Select "Raw image " from the pull down list of
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acquisition modes and then click on "Acquire" button next to the selector to view an
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image that is not corrected.
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#  Leginon/Correction/Toolbar> Select "Both Channels" in the channel number
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selector so that the next steps will acquire images for both correction channels.
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#  Leginon/Correction/Toolbar> Select "Dark reference" in the acquisition mode
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selector and then click "Acquire" to acquire the Dark reference image for this
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particular camera configuration.
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#  Leginon/Correction/Toolbar> Select "Bright reference" and repeat the acquisition
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to obtain the Bright reference.
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#  Leginon/Correction/Toolbar> Select "Channel 0" in the channel number
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selector so that the next step will acquire only one image.
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#  Leginon/Correction/Toolbar> Select "Corrected image" and then "Acquire" to view
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the corrected image. A corrected image should be free of artifacts and have smaller
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standard deviation than the raw image, in general.
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#  Repeat steps 3-14 for all the images and bin sizes that will be used:
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#  If [[Bright and Dark reference images#Correction-Plan|a pixel, a column/row]] or a [[Bright and Dark reference images#Bad-Region-Correction|region]] gives bad values in the bright or dark image
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after a few trials, it may be excluded in all corrected images.
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*Bright/Dark Reference Image Need for the Example MSI with 4kx4k camera:*
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|*Dimension after binning*|*Bin*|*number of correction channels*|*Notes*|
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|4096|1|1 or 2 if used for tomo preset| |
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|1024|4|2|_(1)_|
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|1024(centered)|1|1|_(2)_|
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|512|8|2|_(3)_|
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|512 (centered)|1|1|_(3)_|
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_(1)_-This camera configuration is used in preset beam shift alignment even if you don't use it for a preset.
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_(2)_-This camera configuration is used in Manual Application Manual Focusing even if you don't use it for a preset.
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_(3)_-These camera configurations are used in preset image shift alignment even if you don't use it for a preset.
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h2. Image Despike
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The Despike feature removes random bright or hot pixels from the acquired images. This
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hot pixel is assigned the average intensity of the surrounding area, a circle of the radius
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which is entered in Neighborhood Size. The Despike Threshold is the number of standard
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deviations away from the mean that qualifies a pixel for despike correction. The despike
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affects the flat-field corrected image saved on the disk and can not be recovered.
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Therefore, use a minimal neighborhood size to avoid artifact and set the threshold high to
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avoid over-despiking.
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Activation of this feature and its parameter settings are defined when in the pop-up dialog for "Edit Correction Plan".  See below.
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h2. Correction Plan
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Bad Pixel, Rows and Bad Cols are used to crop portions of the image that do not read
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well off of the digital camera. The values entered into here are determined empirically for each
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instrument that Leginon operates on. If one column or row of the images is incorrect,
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measure the location of the row and column that need to be removed from this image. These
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values should then be entered as a sequence of values separated by commas by editing the
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Plan. Click Save after adjusting.
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Individual bad pixel can also be corrected by its surrounding pixels. Choose these
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pixels with the selection tool on the image and then click on "Grab From Image".
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h2. Find A Single Bad Pixel
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When a single pixel is defected, it may not be easy to find it on a large image, even if
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it changes the stats dramatically. A tool is available to help finding these pixels:
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#  Leginon/Correction> Acquire either a corrected image that shows the bad
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stats.
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#  Leginon/Correction/Toolbar> Left-click on the !http://emg.nysbc.org/software/leginon/images/icons/stagelocations.png!
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button to "Add extreme points to bad pixel list". There
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#  Leginon/Correction/Tools> Left-click on the "Add Region" tool that looks like
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"+". This adds the selected bad region to the bad pixel plan.
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#  Leginon/Corrections> Acquire a corrected image in the same configuration to
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check if the apearance improves.
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h2. Bad Region Correction
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Note: Bad region correction are corrected pixel-by-pixel.  This can be *computational intensive* if a large region is included.  If flat-field correction alone gives reasonable result, you should minimize usage of the this function. 
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When a large region is covered by a fallen chip, image correction through bright/dark reference may not be sufficient to produce a spike-free image since the bright and dark values in the region are almost identical. To add such a large region into bad pixel plan, do the following:
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#  Leginon/Correction> Acquire either a bright or corrected image that shows the
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bad region clearly.
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#  Leginon/Correction> Use "Regions" target tool next to the image to enclose the
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bad region. The corners that the target tool identifies can be larger than the bad
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region but should be close to its size so that not too much is corrected.
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#  Leginon/Correction/Tools> Left-click on the "Add Region" tool that looks like
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"+". This adds the selected bad region to the bad pixel plan.
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#  Leginon/Corrections> Acquire a corrected image in the same configuration to
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check if the appearance improves.
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[[Pixel Size Calibration|< Pixel Size Calibration]] | [[Image Shift matrix calibration|Image Shift matrix calibration >]]
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