Difference between revisions of "34ID-E Data Analysis Overview"
m (→Data types and formats: linke to wikipedia nexus data format page) |
|||
| (5 intermediate revisions by the same user not shown) | |||
| Line 4: | Line 4: | ||
A wide variety of measurements can be carried out at 34ID-E: white beam or mono beam, step scans or slew scans, with area detectors or point detectors, depth-resolving or not, etc. Hence a collection of tools are developed to tackle different types of data sets. | A wide variety of measurements can be carried out at 34ID-E: white beam or mono beam, step scans or slew scans, with area detectors or point detectors, depth-resolving or not, etc. Hence a collection of tools are developed to tackle different types of data sets. | ||
A majority of analysis and visualization functions are built into '''[[LaueGo]]''', a package developed at 34ID-E based on [[IGOR Pro]] which runs on a single PC or Mac. | A majority of analysis and visualization functions are built into '''[[LaueGo]]''', a package developed at 34ID-E based on [[IGOR Pro]], which runs on a single PC or Mac. A few heavier tasks require using a multi-node Linux cluster at APS. | ||
== Data types and formats == | == Data types and formats == | ||
* Each exposure of an [[34ID-E Detectors|area detector]], if file-saving is turned on, creates a file containing 2D data. By default our detector images are saved in the [[NeXus format] | * Each exposure of an [[34ID-E Detectors|area detector]], if file-saving is turned on, creates a file containing 2D data. By default our detector images are saved in the [[wikipedia:Nexus (data format)|NeXus format]], which is based on [[wikipedia:Hierarchical Data Format | HDF-5]]. | ||
** Note: with special configurations, such as the [[fly-scan mode]], multiple exposures can be saved in a single data file as a 3D array. | ** Note: with special configurations, such as the [[fly-scan mode]], multiple exposures can be saved in a single data file as a 3D array. | ||
* Each scan automatically creates a *.mda file that is sequentially numbered. The mda file stores motor positions and pre-selected scaler counts at each scan step. | * Each scan automatically creates a *.mda file that is sequentially numbered. The mda file stores motor positions and pre-selected scaler counts at each scan step. | ||
| Line 15: | Line 15: | ||
== Types of Analysis == | == Types of Analysis == | ||
=== Depth-resolved scans (wire scans) === | === Depth-resolved scans (wire scans) === | ||
Data from depth-resolved measurements requires [[Reconstruction of Depth-Profiling Data | reconstruction]]. A reconstruction takes a depth-profiling wire scan data as input, and generates a series of 2D image files each representing the diffracted intensities from a specific depth along the x-ray's penetration. The process is carried out by | Data from depth-resolved measurements requires [[Reconstruction of Depth-Profiling Data | reconstruction]]. A reconstruction takes a depth-profiling wire scan data as input, and generates a series of 2D image files each representing the diffracted intensities from a specific depth along the x-ray's penetration. The process is carried out by the computer cluster, and can be submitted through [[ORNL Client]]. | ||
The reconstruction process is the same for white-beam or mono-beam scans. | The reconstruction process is the same for white-beam or mono-beam scans. Reconstructed image files are also written in NeXus format. | ||
=== White-beam Laue images === | === White-beam Laue images === | ||
| Line 23: | Line 23: | ||
''Main Article: [[Single Laue Image Analysis with LaueGo]]'' | ''Main Article: [[Single Laue Image Analysis with LaueGo]]'' | ||
Single Laue images, depth-reconstructed or not, can be indexed with [[LaueGo]]. One can index a single Laue Image and get the crystal orientation, deviatoric strain, predict | Single Laue images, depth-reconstructed or not, can be indexed with [[LaueGo]]. One can index a single Laue Image and get the crystal orientation, deviatoric strain, predict energies of specific Bragg peaks, or identify the existence of certain phases. | ||
===== Multiple images ===== | ===== Multiple images ===== | ||
Indexing of a large number of images can be automated on the Linux cluster through [[ORNL Client]]. It is recommended that one first try indexing a few images with LaueGo and get all the input parameters optimized before submitting a batch indexing job. | Indexing of a large number of images can be automated on the Linux cluster through [[ORNL Client]]. It is recommended that one first try indexing a few images with LaueGo and get all the input parameters optimized before submitting a batch indexing job. | ||
| Line 38: | Line 39: | ||
=== Scaler data (mda files) === | === Scaler data (mda files) === | ||
{{Incomplete}} | {{Incomplete}} | ||
There are a few ways | There are a few ways to visualize scaler scan data: | ||
#Plotting window by MEDM (for 1D scans) | #Plotting window by MEDM (for 1D scans only) | ||
#scanSee (1D and 2D) | #scanSee (1D and 2D) | ||
#LaueGo has built-in functions for reading and displaying mda files | #LaueGo has built-in functions for reading and displaying mda files | ||
#An IDL utitlity on beamline PC can display 2D mda data | #An IDL utitlity on beamline PC can display 2D mda data | ||
== See Also == | == See Also == | ||
* [[LaueGo]] | |||
* [[Reconstruction]] | |||
* [[peakSearch program]] and [[Euler program]] | |||
Latest revision as of 18:39, 21 October 2013
| (This article/section is incomplete, please check back again or help expanding it) |
A wide variety of measurements can be carried out at 34ID-E: white beam or mono beam, step scans or slew scans, with area detectors or point detectors, depth-resolving or not, etc. Hence a collection of tools are developed to tackle different types of data sets.
A majority of analysis and visualization functions are built into LaueGo, a package developed at 34ID-E based on IGOR Pro, which runs on a single PC or Mac. A few heavier tasks require using a multi-node Linux cluster at APS.
Data types and formats
- Each exposure of an area detector, if file-saving is turned on, creates a file containing 2D data. By default our detector images are saved in the NeXus format, which is based on HDF-5.
- Note: with special configurations, such as the fly-scan mode, multiple exposures can be saved in a single data file as a 3D array.
- Each scan automatically creates a *.mda file that is sequentially numbered. The mda file stores motor positions and pre-selected scaler counts at each scan step.
- Only the motors that are being scanned are recorded in mda files.
- For multichannel analyzer (MCA) fluorescence detectors, total counts of each window of channels are recorded as scalers, and stored in the mda files.
Types of Analysis
Depth-resolved scans (wire scans)
Data from depth-resolved measurements requires reconstruction. A reconstruction takes a depth-profiling wire scan data as input, and generates a series of 2D image files each representing the diffracted intensities from a specific depth along the x-ray's penetration. The process is carried out by the computer cluster, and can be submitted through ORNL Client.
The reconstruction process is the same for white-beam or mono-beam scans. Reconstructed image files are also written in NeXus format.
White-beam Laue images
Single image
Main Article: Single Laue Image Analysis with LaueGo
Single Laue images, depth-reconstructed or not, can be indexed with LaueGo. One can index a single Laue Image and get the crystal orientation, deviatoric strain, predict energies of specific Bragg peaks, or identify the existence of certain phases.
Multiple images
Indexing of a large number of images can be automated on the Linux cluster through ORNL Client. It is recommended that one first try indexing a few images with LaueGo and get all the input parameters optimized before submitting a batch indexing job.
Each multiple-indexing job creates an xml report file that contains the indexing results for each image. This report can be imported to LaueGo for further analysis, such as strain refinement, 2D/3D plotting, pole figures, etc.
Monochromatic beam data (energy scans)
Mono beam are mostly used for energy scans near specific Bragg peaks to measure lattice d-spacings, they can be done with or without depth-profiling.
Depth-resolved wire scans need to be reconstructed first.
Energy scan data can be analyzed with functions listed in the "E scans" tab of LaueGo.
Scaler data (mda files)
| (This article/section is incomplete, please check back again or help expanding it) |
There are a few ways to visualize scaler scan data:
- Plotting window by MEDM (for 1D scans only)
- scanSee (1D and 2D)
- LaueGo has built-in functions for reading and displaying mda files
- An IDL utitlity on beamline PC can display 2D mda data
