Running the application » History » Version 6
Amber Herold, 06/18/2010 03:52 PM
1 | 1 | Amber Herold | h1. Running the application |
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5 | h2. Import Notes about Image Intensity Recorded through |
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6 | Tomography Node |
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10 | Tomography node save the images in a different format from other Acquisition nodes. By |
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11 | default, the flat-field correct CCD counts are multiplied by 10 and converted to signed |
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12 | 16-bit integer before the image is displayed and saved. This makes CCD counts of 3276.8 or |
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13 | larger overflow to negatives. Other Leginon Acquisition images are saved as float without |
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14 | manipulation. |
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17 | To avoid this problem, find out what exposure time corresponds to the fractionated dose |
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18 | from your tilt angle step and range and total dose and take an image at tomo preset with |
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19 | such an exposure in Navigation node. You will need to reduce the total dose if a good |
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20 | fraction of the counts are larger than 3200 even though it would not appear to be saturated |
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21 | in the float scale without the 10x factor. Alternatively, change the scale factor in |
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22 | Tomography node. |
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27 | |||
28 | h2. Multiscale Imaging |
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31 | |||
32 | * Preset image shift alignment/beam shift alignment are the same as in MSI |
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33 | application |
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36 | 5 | Amber Herold | * New dark/bright references should be reacquired for "tomo" preset that acquires the |
37 | 1 | Amber Herold | final data. It is best to do this at the same dose per tomography image calculated from |
38 | the total dose, the tilt parameters, and the dose measurement. |
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41 | * For best focusing result, perform autofocus at the same magnification as the |
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42 | tomography data collection, align microscope well at the eucentric focus and the |
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43 | rotation center and save them before data collection. |
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51 | h2. Using Tomography Preview |
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54 | |||
55 | * Preview targets (pink) can be selected when selecting targets in "Tomography |
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56 | Targeting" |
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57 | |||
58 | |||
59 | * When the targets are processed, targets that are of the type "preview" are |
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60 | processed before focus and acquisition targets. |
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61 | |||
62 | |||
63 | * Tomography Preview node acquires a image at the preview target using "preview" |
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64 | preset which should be set at minimal dose. |
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71 | |||
72 | h2. Dose Measurement |
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76 | If "Measure Dose before collection" is checked in Tomography node, the stage will be |
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77 | moved to the reference target and a dose image of the "tomo" preset will be acquired (center |
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78 | 512x512 of whateven binning of the preset) before each tilt series if the interval between |
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79 | the series is longer than the limit time set in the settings of Dose Measurement node. The |
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80 | measured value will then be used to recalculate the proper exposure time for tomography |
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81 | imaging. |
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83 | |||
84 | For this function to behave properly, the followings should be done during |
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85 | operation: |
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86 | |||
87 | |||
88 | * One, and only one, "reference" target should be selected in either "Square |
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89 | Targeting" or "Hole Targeting" or "Tomography Targeting" node. The reference target |
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90 | should be of either a broken square or a empty hole if no broken square can be |
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91 | found. |
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92 | |||
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94 | * "Measure Dose" before collection should be selected in Tomography node. |
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97 | * "Exposure time max/min" in Tomography node should be in a range that can accommodate |
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98 | the electron beam fluctuation over time. |
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106 | h2. Align Zero Loss Peak |
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110 | This function applies only to Gatan energy filter EFTEM. If "Align ZLP before |
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111 | collection" is checked in Tomography node, the stage will be moved to the reference target |
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112 | and starts the procedure to align zero loss peak before each tilt series if the interval |
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113 | between the series is longer than the limit time set in the settings of Dose Measurement |
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114 | node. |
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115 | |||
116 | |||
117 | For this function to behave properly, the followings should be done during |
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118 | operation: |
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119 | |||
120 | |||
121 | * One, and only one, "reference" target should be selected in either "Square |
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122 | Targeting" or "Hole Targeting" or "Tomography Targeting" node. The reference target |
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123 | should be of either a broken square or a empty hole if no broken square can be found. |
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124 | This is the same reference target used for dose measurement. |
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125 | |||
126 | |||
127 | * "Align ZLP" before collection should be selected in Tomography node. |
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134 | |||
135 | h2. Low Magnification Model Fitting |
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138 | |||
139 | The fitting of optical axis offset does not always works if the offset is so large that |
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140 | the feature moves out of view with even a small tilt. In such a case, it is worth first |
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141 | collect a tomography series at a lower magnification to define roughly the model. |
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144 | At beginning of each session, or forced by the user, the model is initialized. By |
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145 | default, at the initialization, Tomography node uses past fitting results that show good |
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146 | agreement with the experimental data at the magnification of the preset used. If a good |
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147 | model is not found, that from lower magnifications will be used. It is possible to force the |
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148 | node to use a model fitted at a particular magnification by selecting it in |
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149 | Tomography/Settings/Model. |
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151 | |||
152 | Therefore, we recommend that, in case of fitting failure on good contrast images, the |
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153 | followings should be done: |
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156 | 3 | Amber Herold | # Tomography/Settings/Image Acquisition> change the preset to "hl". |
157 | # Tomography/Settings> adjust Tilt and Exposure parameters to match. |
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158 | # Acquire the tiltseries images. |
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159 | # If the tracking is good, change the preset back. |
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160 | # Tomography/Settings/Model> Initialize with the model of (the mag of "hl" |
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161 | 1 | Amber Herold | preset). |
162 | 3 | Amber Herold | # Acquire the tomo-series. |
163 | # If tracking is good, change back to Initialize with the model of "this preset and |
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164 | 1 | Amber Herold | lower" mag. |
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172 | h2. What is a Good Tilt-Axis Model? |
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176 | 5 | Amber Herold | The goniometer-tilt-axis-based tracking model developed by Zheng et. al. corrects the |
177 | specimen height (z-axis) by a change of defocus using measured shift of feature shifts in |
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178 | 1 | Amber Herold | the images (x and y-axes). The tracking in the x and y directions does not involve the use |
179 | 5 | Amber Herold | of such model, but is done by smooth curve fitting or preceding tilts. Therefore, to judge |
180 | 1 | Amber Herold | the adequacy of the model, one should check the resulting defocii of the images in the |
181 | series remain unchanged. |
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183 | |||
184 | On the other hand, the feature tracking in x and y is likely to fail only if the tilting |
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185 | does not induce a smooth shift of the imaging feature a sudden drop of specimen position at |
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186 | a particular tilt angle often throws off the smooth curve fitting. It is possible to reduce |
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187 | such effect by increasing the number of data points included in the smoothing as set in the |
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188 | model section of the tomography node settings window. Otherwise, the goniometer need to be |
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189 | serviced. |
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195 | h2. Checking and Improving Tilt-Axis Model |
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199 | Test runs should be done at the magnification, defocus, and tilts up to the highest |
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200 | values planned for the real ones with a specimen with isotropic features in view and |
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201 | adjusted to eucentric height. Tilt steps should be made to allow at least 15 images taken |
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202 | per tilt direction. |
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206 | 4 | Amber Herold | h3. First Test Run: Fixed Model |
207 | 1 | Amber Herold | |
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209 | |||
210 | The first time the tomography application is used on a microscope, all model |
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211 | parameters are default to zero. A test run should be done with the specimen at eucentric |
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212 | height and all default settings including "keep the tilt axis parameters fixed" activated. |
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213 | If the feature tracking is good, and the defocii of the images in the tilt series do not |
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214 | significantly changed, the goniometer behavior and camera alignment are close to ideal, |
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215 | and no improvement of the model is required. |
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218 | If the xy tracking deteriorates quickly in the first few tilts, the magnification |
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219 | should be dropped so that tracking is possible through out the tilt series. Once a rough |
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220 | model is established, refinement can then be done at higher magnifications. |
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226 | 4 | Amber Herold | h3. Runs to Improve the Model-Fitting |
227 | 1 | Amber Herold | |
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229 | |||
230 | A complete tilt model fitting is difficult with small number of data points or at only |
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231 | low tilts. Therefore, two tilt series need to be taken in order to get a good averaged |
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232 | model that is later fixed. |
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235 | 4 | Amber Herold | # tomography/settings/model>deactivate "keep the tilt axis parameters |
236 | 1 | Amber Herold | fixed". |
237 | 4 | Amber Herold | # tomography/settings/model>initialize the model with "this preset only" unless |
238 | 1 | Amber Herold | this is a refinement of <link linkend="Tomo_low_mag_fitting">a rough model obtained at |
239 | a lower magnification</link>, in which case, initialize the model with "this preset |
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240 | and lower mags". |
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241 | 4 | Amber Herold | # tomography/toolbar>click on "reset learning" !http://emg.nysbc.org/software/leginon/images/icons/refresh.png! to have |
242 | 1 | Amber Herold | a fresh start of tilt series data included in the fitting. |
243 | 4 | Amber Herold | # Presets Manager>send the "tomo" preset to scope. |
244 | # tomography>Start the tilt series image collection by clicking on "Simulated |
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245 | 1 | Amber Herold | Target" tool. |
246 | 4 | Amber Herold | # repeat 4 and 5 to dynamically fit the model the second time if the first one goes |
247 | 1 | Amber Herold | to completion. |
248 | 4 | Amber Herold | If the target shifts away during the run, reduce the magnification, repeat 1 |
249 | 1 | Amber Herold | through 9 in this procedure and then return to the higher, intended mag and refined |
250 | the model using the same procedure and proper setting for refinement as mentioned in |
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251 | 2. |
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252 | 4 | Amber Herold | # Check on web image viewer to see if the result of the second run in step 6 |
253 | 1 | Amber Herold | produces images of constant defocus through out each half of the tilt seriese. |
254 | 4 | Amber Herold | # If the model is good, activate "keep the tilt axis parameters fixed" in the |
255 | 1 | Amber Herold | tomography settings. |
256 | 4 | Amber Herold | # Repeat step 2. Other than reset the learning, the tool produces an output of image |
257 | 1 | Amber Herold | shift you should copy down and apply to the "tomo" preset in the future runs. |
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266 | |||
267 | h2. Understand the results of the model fitting |
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271 | 5 | Amber Herold | If the above procedure does not yield a good model, it is necessary to study the graphs |
272 | 1 | Amber Herold | output by the run to determine possible causes and derive the best fixed model that at least |
273 | work for most angles. |
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274 | |||
275 | |||
276 | Figure 1 shows a typical result from the first dynamically fitted tilt series run. x and |
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277 | y axes contains the tilt axis and are referenced to columns and rows on the images acquired. |
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278 | z-axis is parallel to the electron beam. The "Prediction" data in the x and y-axis plot is |
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279 | 5 | Amber Herold | the extrapolated result of the smooth curve fitting from preceding (usually 4) tilts to the |
280 | 1 | Amber Herold | current tilt angle. The "Position" is where features on the specimen end up to be relative |
281 | to the origin of the image shift at the scope as determined by correlation of images. Both |
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282 | "Prediction" and "Position" are expressed in microns. The "Feature" is the shift of the |
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283 | feature on the image. It corresponds to the difference between "Prediction" and "Position" |
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284 | and is expressed in pixels of the image acquired. The z-axis "Prediction" is the correction |
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285 | of defocus, i.e., specimen z-height change, the current model suggests and applied for each |
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286 | tilt angle to keep the specimen focused. Originally, it is possible to measure defocus at |
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287 | each tilt and obtain "Measured" values in this plot. However, the function is currently |
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288 | disabled because the procedure does give accurate results. |
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289 | |||
290 | |||
291 | According to the Zheng et. al. model, the tilt-axis can be characterized by three |
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292 | parameters: phi, the angle between the tilt axis and the detector x axis (column), offset, |
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293 | the distance between the center of the detector and the tilt axis on the xy plane, and z0, |
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294 | the distance between the specimen from the xy plane that contains the tilt axis. If the tilt |
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295 | axis is parallel to x-axis of the detector, and that the model does not change through the |
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296 | tilt series, y-axis(row) "Prediction" and "Position" should remain constant. While the same |
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297 | values for x-axis follows a cosine curve as it tilts if the only deviation from the ideal |
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298 | model is an offset of the tilt axis from detector center in x-direction (non-zero offset). |
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299 | On the other hand, if the only deviation the ideal model is an offset in z direction |
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300 | (non-zero z0) |
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301 | |||
302 | |||
303 | As a first tilt series used in the model fitting, the data is not fitted until it |
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304 | 5 | Amber Herold | accumulate enough data points and spread over more tilts. We arbitrarily select 30 degrees as |
305 | 1 | Amber Herold | the starting angle where the fit is started. As can be seen in Figure 1, the model is |
306 | significantly different from the initial as z-axis "Prediction" jumps once the fitting is |
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307 | started. In particular, the model z0 which corresponds to the offset of the specimen from |
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308 | the tilt axis in z direction dominates deviation. Such problem is evident by the |
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309 | 5 | Amber Herold | near-straight line feature shift in x-axis over more than 1 um. There is also some offset in |
310 | 1 | Amber Herold | x direction since the "Prediction" and "Position" flattens somewhat as it approaches zero |
311 | tilt. The tilt axis has minimal tilt from x-axis since in the y-direction, despite the bump |
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312 | at about 40 degrees, the range of variation in the whole tilt series is about 0.06 |
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313 | um. |
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314 | |||
315 | |||
316 | 6 | Amber Herold | *Figure 1* |
317 | !http://emg.nysbc.org/software/leginon/images/images/tomoxyz1.png! |
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318 | 1 | Amber Herold | |
319 | |||
320 | By activate "show model parameters" check box in the viewer, more plots are shown |
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321 | (Figure 2). phi and "optical axis" offset remain fixed below 30 deg while z0 is recalculated |
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322 | at each tilt. As you can see, the fitting of the former two parameters are not very stable |
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323 | in this first trial. Therefore, we need to do the second run. |
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324 | |||
325 | |||
326 | 6 | Amber Herold | *Figure 2* |
327 | !http://emg.nysbc.org/software/leginon/images/images/tomomodel1.png! |
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328 | 1 | Amber Herold | |
329 | |||
330 | Figure 3 shows the z-axis plot of the second run since the x and y does not change |
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331 | significantly. Figure 4 shows its corresponding model parameters. The zero and first tilt |
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332 | uses the initial model and the rest are fitted dynamically. In this run, because more than |
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333 | one tilt series is found in the memory since last "reset learning", the model fitting starts |
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334 | after the first tilt image is acquired. model parameters are rather stable over the whole |
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335 | tilt series and suggests that the tilt axis is tilted from x-axis by about -1.3 degree, and |
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336 | offset from the center of the detector by -0.6 um, and the specimen is off from eucentric |
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337 | height by about -0.7 um |
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338 | |||
339 | |||
340 | 6 | Amber Herold | *Figure 3* |
341 | !http://emg.nysbc.org/software/leginon/images/images/tomoz2.png! |
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342 | 5 | Amber Herold | |
343 | 1 | Amber Herold | |
344 | 6 | Amber Herold | *Figure 4* |
345 | !http://emg.nysbc.org/software/leginon/images/images/tomomodel2.png! |
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346 | 1 | Amber Herold | |
347 | |||
348 | |||
349 | |||
350 | Although it is not possible to maintain perfect defocus prediction in the full range of |
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351 | the tilt by using a fixed model, we found that the overall performance is better if an |
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352 | average tilt axis model that works well in the mid-range tilt is used as a fixed model. For |
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353 | example, for the behavior in the above figure, we choose: |
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354 | |||
355 | |||
356 | |||
357 | |||
358 | Use these custom values as initial model and turn on "Keep the tilt axis parameters |
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359 | fixed". If the result is good, judging by consistent defocus and target tracking through out |
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360 | the tilt series, this model will be saved in the database as best model automatically, and |
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361 | you can revert back to initialize with the model of "only this preset". |
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362 | |||
363 | |||
364 | |||
365 | |||
366 | |||
367 | h2. Failure of xy feature tracking |
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368 | |||
369 | |||
370 | |||
371 | feature tracking in x and y axes is a 2nd order polynomial fit of preceeding data |
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372 | points. The default uses 5 data points. When a sudden jump occurs in the tracking error, it |
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373 | tend to follow the trend of the last point. If the jump is a temporary clich in the |
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374 | goniometer, this tend to over correct the tracking error and eventually loose track as shown |
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375 | in Figure 5. A possible fix is to increase the number of data points in the fitting. This |
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376 | can be set in the tomography setting "Smooth n tilts for defocus prediction". 4 in defocus |
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377 | prediction is equivalent to 5 points (n+1) for xy tracking. |
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378 | |||
379 | |||
380 | 6 | Amber Herold | *Figure 5* |
381 | !http://emg.nysbc.org/software/leginon/images/images/tomoxbad.png! |
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382 | 1 | Amber Herold | |
383 | |||
384 | |||
385 | |||
386 | |||
387 | h2. Large tracking error between the first and second tilt |
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388 | images |
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389 | |||
390 | |||
391 | |||
392 | The first image in each tilt group of the tilt series at the "start" angle (normally 0 |
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393 | deg) and the second image at tilt of "step" angle from the "start" angle do not use the |
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394 | fitted model. It is assumed that the eucentric height judged by stage alpha wobbling in the |
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395 | "Tomo Focus" node gives a stage height that the tracking of feature by such a small tilt |
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396 | would be good enough. In most cases this is a reasonable assumption. However, we have had |
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397 | experience of goniometer alignment problem where the assumption fails. The symptom is |
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398 | illustrated in Figure 6 below. Note that the Feature tracking error is displayed as |
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399 | percentage of the image length. |
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400 | |||
401 | |||
402 | 6 | Amber Herold | *Figure 6* |
403 | !http://emg.nysbc.org/software/leginon/images/images/tomoz0bad.png! |
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404 | 1 | Amber Herold | |
405 | |||
406 | This tilt series was taken with a starting angle of zero and at an image size of < 1 |
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407 | um. As can be seen here, apart from the +2 and -2 degree tilts, the tracking error was less |
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408 | than 2 % of the image. Only the tracking of the feature between 0 and +/- 2 degrees are |
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409 | large. At close to 20 % error, this made the overlap between +/- 2 degrees unacceptable and |
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410 | often cause popular alignment programs to misalign the two half of the series. |
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411 | |||
412 | |||
413 | The first solution is of course to report it to your microscope service engineer. When |
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414 | we had this problem, many users noticed that it was difficult to adjust stage to eucentric |
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415 | height manually with alpha wobbler. Features jumped while the goniometer changed rotation |
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416 | direction. In addition, different magnitude of tilt range suggests different eucentric |
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417 | heights. It is not easy to fix this, so it might take a while. |
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418 | |||
419 | |||
420 | Before the hardware is fixed physically, it is still possible collect tomograms. The |
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421 | model fitting of the overall curve in the above case gave z0 of +5 um through the whole tilt |
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422 | series (Figure not shown). Therefore, by moving the stage up by such an amount after the |
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423 | stage-tilt-based autofocusing can bring us to the correct height for tomography. This can |
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424 | be acheived by saving the "tomo eucentric" focus current to the database, align rotation |
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425 | center for this stage height and focus. Then change the correction type of the |
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426 | "Beam_Tilt_Fine" focusing step to "Stage Z". |
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427 | |||
428 | |||
429 | |||
430 | |||
431 | |||
432 | h2. Failure of model-based correction |
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433 | |||
434 | |||
435 | |||
436 | The model used in the defocus correction in Leginon tomography node is a very simplified |
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437 | one. There are a few cases when the approach fails. Here are ones that we have |
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438 | encountered: |
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439 | |||
440 | |||
441 | |||
442 | h2. Y-axis looping |
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443 | |||
444 | |||
445 | |||
446 | The microscope goniometer does not move on only the tilt axis. With its complex |
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447 | structure, a common problem is that when the stage is highly tilt, the position slips in |
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448 | the y-direction. This is known as looping. Figure 7 shows an example of this problem. |
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449 | |||
450 | |||
451 | 6 | Amber Herold | *Figure 7* |
452 | !http://emg.nysbc.org/software/leginon/images/images/tomoxyloop.png! |
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453 | 1 | Amber Herold | |
454 | |||
455 | While the x-axis position shifts monotonically as a stable model should be, the y-axis |
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456 | in the positive tilt direction changes little from 0-30 degrees before it increases |
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457 | rapidly after 30 degrees. Even though the tracking in xy plane is still good, the defocii |
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458 | correction at these higher tilts may no longer be correct if the tilt axis parameters are |
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459 | fitted dynamically. Figure 8 shows the model parameters of the same tilt series where the |
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460 | fitted phi and offset starts to change above 30 degrees even though the tilt axis has not |
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461 | moved according to the shrinking behavior of the images during the tilts. Note that in |
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462 | this particular case the looping problem is still mild so that the over-correction is not |
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463 | very strong. only a small slope change is resulted in z0 prediction. In worst cases, the |
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464 | defocus over-correction is so large that the adjacent images can not correlate properly |
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465 | and even the xy tracking would fail. The spikes around zero tilt is a display data sorting |
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466 | error of the identical starting tilt of the two tilt groups. |
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467 | |||
468 | |||
469 | 6 | Amber Herold | *Figure 8* |
470 | !http://emg.nysbc.org/software/leginon/images/images/tomomodelloop.png! |
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471 | 1 | Amber Herold | |
472 | |||
473 | Other than asking microscope service engineer to fix the looping, one can find the |
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474 | best fixed model in the series to apply to future tilt data collection. To make the fixed |
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475 | model permantly saved to the database, follow these steps: |
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476 | |||
477 | |||
478 | * tomography/settings/model>activate "keep the tilt axis parameters |
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479 | fixed". |
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480 | |||
481 | |||
482 | * tomography/settings/model>initialize the model with "custom values". Enter best |
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483 | estimate of the fixed model. For example, in the positive direction, enter phi as |
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484 | -2.17 degrees and axis offset as -1.52 um. since these are the stable values up to the |
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485 | point the y-looping starts. |
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486 | |||
487 | |||
488 | * tomography>collect a full tilt series. If the run is successful with good |
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489 | tracking in all three axis, the model will be saved in the database for this |
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490 | magnification. |
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491 | |||
492 | |||
493 | * tomography/settings/model>From now on, you can initialize the model with "only |
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494 | this preset" or "this preset and lower mags" |
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495 | |||
496 | |||
497 | |||
498 | |||
499 | |||
500 | |||
501 | |||
502 | h2. Grid slips between the first and second tilt directions |
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503 | |||
504 | |||
505 | |||
506 | When the holder does not hold the grid tightly, the grid slips to a different position |
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507 | when the first tilt direction ends and the goniometer quickly returns to zero tilt. |
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508 | Leginon is designed to adjust the target before the second tilt group starts. The default |
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509 | setting for this function is to use only the parent image (i.e. one ancestor) where the |
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510 | target comes from as reference. If the slip is larger than the size of the parent image, |
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511 | the adjustment may fail, and a random target would be acquired in the second tilt |
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512 | group. |
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513 | |||
514 | |||
515 | Starting from Leginon 1.6, the target adjustment can be done with all ancestor images |
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516 | of the target by choosing "all" in the acquisition part of the tomography node setting to |
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517 | adjust target with all ancestors. The node "Taget Adjustment" limits the lowest |
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518 | magnification that this target adjustment would go up in ancestry. The default is at 300x |
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519 | so that the presence of the objective aperture does not create difference in the reaquired |
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520 | ancestor image from its original. |
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521 | |||
522 | |||
523 | |||
524 | |||
525 | |||
526 | h2. Strong and continuous specimen drift |
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527 | |||
528 | |||
529 | |||
530 | The model used in Leginon considers any shift of feature in the image a result of tilt |
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531 | axis not aligning to the center of the detector. With the phi and offset fixed, all errors |
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532 | are accumulated in z0 and results in bad defocus correction. There is no solution to this |
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533 | at the moment. |