Difference between revisions of "MuonCalib Tutorial"

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'''Calibration framework'''
 
'''Calibration framework'''
  
A clear Wiki page on the Calibration Framework by Domizia and Niels can be found on the [https://uimon.cern.ch/twiki/bin/view/Atlas/MuonCalibrationFramework MuonCalibrationFramework Wiki].
+
A clear Wiki page on the Calibration Framework by Domizia and Niels can be found on the [https://uimon.cern.ch/twiki/bin/view/Atlas/MuonCalibrationFramework MuonCalibrationFramework Wiki]. At this site, the Calibration EDM is explained.
  
  
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Maybe needed to explain the concept of segments and the calibration EDM, is to be written (work in progress). A starting point of Calibration Segments and its scope in the Reconstruction EDM can be found in a presentation given by Zdenko during the ATLAS Muonweek september-2005 called [http://agenda.cern.ch/fullAgenda.php?ida=a057588 Calibration Segment Ntuple]
 
Maybe needed to explain the concept of segments and the calibration EDM, is to be written (work in progress). A starting point of Calibration Segments and its scope in the Reconstruction EDM can be found in a presentation given by Zdenko during the ATLAS Muonweek september-2005 called [http://agenda.cern.ch/fullAgenda.php?ida=a057588 Calibration Segment Ntuple]
  
 +
==Getting started==
 +
In order to get started one should know that this field is prone to many changes over time. Backward compatibility is surely broken since the ntuple format changed a lot in the period of november 2005. The ntuple format is defined by the MuonCalib package (''MuonCalibNtuple''), and the analysis package needs a certain ntuple format to be able to fill the MuonCalib EDM classes offline. In the following sections, recipes will be provided for different kinds of ntuple formats.
  
==Making segment ntuples==
+
To summarize the procedure:
 +
* Choose your ntuple-format and wich version to run in
 +
* Follow the recipes below to make your ntuple, customize jobOption file where needed
 +
* Build the appropriate version of the CalibSegmentAnalysis package (depending on ntuple format)
 +
* Run your analysis, customize the analyse routine where needed
  
'''Setting up ATHENA'''
+
'''Different <font color=red>versions</font> of Ntuple Content'''
  
Making segment ntuples from scratch can be done with Athena running on release 10.5.0 or higher. It is recommended to run at the most recent release, in order to be up-to-date. If you do not have an ATLAS account yet you can get an account [https://uimon.cern.ch/twiki/bin/view/Atlas/WorkBookGetAccount here].  
+
Currently, there are two different formats of the Calibration Segment Ntuple, described in the following tables:
 +
* [[CalibSegmentNtupleContentA|Calibration Segment Ntuple Content A]]. Information on patterns, segments en Mdt hits. All segments appear twice on the ntuple since a refit-flag is performed during ntuple-writing. This ntuple should be obsolete since release 11.X.0.
 +
* [[CalibSegmentNtupleContentB|Calibration Segment Ntuple Content B]]. Information on patterns, segments and hits of all technologies (Mdt's containing extra calibration information, the other technologies are not yet fully implemented). No extra refit is performed, so no double segments. In addition, truth information and event information (run and event number) is available.
 +
* [[CalibSegmentNtupleContentC|Calibration Segment Ntuple Content C]]. Is non-existent at the moment. It is sure that one will be defined in the future, the difference with Ntuple Content B will be a better description of the other technology hits, and timing information on event-level.
  
The content of the Calibration Segment Ntuple can be found [MuonCalib_NtupleContent here].
+
'''Which <font color=red>recipe</font> to use to make the Ntuple'''
  
The content of the ntuple described in the [http://agenda.cern.ch/fullAgenda.php?ida=a057588 Calibration Segment Ntuple] talk is not available in release 11.0.0 . In order to be able to make ntuples is this format one should use more recent versions of MuonCalib. These have to be checked out from CVS and to be recompiled in the right order (in order to set the libraries in the right way).  
+
The different formats of Ntuples can be produced with different recipes. The following recipes sets up athena and guides you to running the Muon Calibration package. With this running you can proceed to the next section below.
 +
* [[CalibSegmentNtupleRecipeA_1050|Recipe for Ntuple A in 10.5.0]] Works out-of-the-box <font color=red> though outdated </font>
 +
* [[CalibSegmentNtupleRecipeA_1100|Recipe for Ntuple A in 11.0.0]] Works out-of-the-box <font color=red> though outdated </font>
 +
* [[CalibSegmentNtupleRecipeB_1100|Recipe for Ntuple B in 11.0.0]] This recipe requires MuonCalib to be checked out of CVS and to be recompiled. This is a time-costly procedure, but the best available until a newer release is present. <font color=red> RECOMMENDED </font>
 +
* [[CalibSegmentNtupleRecipeB_11X0|Recipe for Ntuple B in 11.X.0]] This release has the new MuonCalib compiled so this should run out-of-the-box.
  
* log on to ''lxplus'':
+
==A deeper look into the jobOptions==
<font color = red> <tt>ssh <username>@lxplus.cern.ch </tt></font>
 
* create a work area (here called ''11.0.0'')
 
<font color = red><tt>mkdir 11.0.0</tt>
 
  
<tt>cd 11.0.0/</tt></font>
+
* For version 10.5.0: a good example of a ''jobOptions'' file that produces segment ntuples is provided in Domizia's public:
* create a ''requirements'' file which should look like this:
+
<font color = red><tt> cp /afs/cern.ch/user/d/domizia/public/MuonCalib_files/myTopOptions.py .</tt></font>
<pre>
+
* For version 11.0.0: a good example of a ''jobOptions'' file that produces segment ntuples is provided in Zdenko's public:
set          CMTSITE          CERN
+
<font color = red><tt> cp /afs/cern.ch/user/z/zvankest/public/MuonCalib_files/myTopOptions.py .</tt></font>
 
 
macro        ATLAS_DIST_AREA  "/afs/cern.ch/atlas/software/dist"
 
macro        ATLAS_RELEASE    "11.0.0"
 
 
 
use          AtlasSettings v* $(ATLhttp://agenda.cern.ch/fullAgenda.php?ida=a057588AS_DIST_AREA)
 
 
 
path_remove  CMTPATH          ${PWD}
 
path_prepend CMTPATH          ${PWD}
 
</pre>
 
* build your CMT environment:
 
<font color = red><tt>source /afs/cern.ch/sw/contrib/CMT/v1r18p20050501/mgr/setup.(c)sh</tt>
 
 
 
<tt>cmt config</tt>
 
 
 
<tt>source setup.(c)sh -tag=opt</tt></font>
 
 
 
* the last command line must be typed in every time you open a new terminal. If you want to fill your ntuple with segments from ATLAS reconstructed muons check out the ''RecExCommon'' package. For other environments (such as CTB etcetera take a closer look at the [https://uimon.cern.ch/twiki/bin/view/Atlas/MuonCalibrationFramework MuonCalibrationFramework] page.
 
<font color = red><tt>cmt co Reconstruction/RecExample/RecExCommon</tt> </font> (at head) or
 
 
 
<font color = red><tt>cmt co -r RecExCommon-version Reconstruction/RecExample/RecExCommon</tt> </font>  for your favorite version. Currently, the head version of RecExCommon fails to run quickly. A working version is for instance RecExCommon-00-04-20.
 
 
 
* build ''RecExCommon''
 
<font color = red><tt>cd Recontruction/RecExample/RecExCommon/RecExCommon-*/cmt </tt>
 
 
 
<tt>cmt config </tt>
 
 
 
<tt>source setup.(c)sh </tt>
 
 
 
<tt>gmake </tt> </font> 
 
 
 
* go to the ''run'' directory and load some auxilliary libraries:
 
<font color = red><tt>cd ../run/ </tt>
 
 
 
<tt>source ../share/RecExCommon_links.(c)sh </tt></font> 
 
 
 
* now we can run Athena, provided to have the right ''jobOptions'' files. (The following command dumps the messages and writes them to the logfile.)
 
<font color = red><tt>athena jobOptions.py | tee athena.log </tt></font> 
 
 
 
'''Running on single muons samples'''
 
 
 
* a good example of a ''jobOptions'' file that produces segment ntuples is provided in Zdenko's public:
 
<font color = red><tt> cp /afs/cern.ch/user/z/zvankest/public/myTopOptions.py .</tt></font>
 
  
 
* you can customize this jobOption file to your own needs...
 
* you can customize this jobOption file to your own needs...
Line 95: Line 63:
 
</pre>
 
</pre>
  
From the ntuple on, we can operate Athena-independent.  
+
From the ntuple produced, one can proceed Athena-independent.
  
 
==Segment analysis==
 
==Segment analysis==
  
'''The Calibration Event Data Model (EDM)'''
+
'''A little word about the Calibration Event Data Model (EDM)'''
  
The MuonCalibration-framework works with a Calibration EDM, which defines the objects used in the Calibration. The structure is more or less like this:
+
The MuonCalibration-framework works with a Calibration EDM, which defines ''the objects'' used in the Calibration. The structure is more or less like this:
* each event contains a certain number of ''Patterns''. Concider these as potential tracks, containing information such as the ''Chi Squared'' of the pattern, the ''track parameters (z0, r0, <math> \vartheta </math>, <math> \varphi </math>, q/p)''. These patterns are described in the class ''MuonCalib::MuonGlobalPattern''. Patterns are built from a number of ''segments''.
+
* each event contains a certain number of ''Patterns''. Concider these as linked segments, as potential tracks, containing information such as the ''Chi Squared'' of the pattern, the ''track parameters (z0, r0, <math> \vartheta </math>, <math> \varphi </math>, q/p)''. These patterns are described in the class ''MuonCalib::MuonGlobalPattern''. Patterns are built from a number of ''segments''.
  
 
* a segment is described by ''MuonCalib::MuonCalibSegment'', which is basically a line segment which matches the hits stored in the segment. So segments describe the premature track at ''chamber level''. A line is given by a vector and a direction. This information can be found on the segment as well, in two co-ordinate systems: the ''global'' ATLAS co-ordinates and the ''local'' chamber co-ordinates.
 
* a segment is described by ''MuonCalib::MuonCalibSegment'', which is basically a line segment which matches the hits stored in the segment. So segments describe the premature track at ''chamber level''. A line is given by a vector and a direction. This information can be found on the segment as well, in two co-ordinate systems: the ''global'' ATLAS co-ordinates and the ''local'' chamber co-ordinates.
Line 112: Line 80:
 
'''The CalibNtupleAnalysis package'''
 
'''The CalibNtupleAnalysis package'''
  
<<work in progress>>
+
Since there exists two ntuple formats, different versions of the ''CalibNtupleAnalysis package'' exist. Recipes to run the skeleton analysis are given here:
At this moment, the tarfile containing the CalibNtupleAnalysis package treats ntuples made by release 10.5.0 and 11.0.0 without updated Calibration Service. Since half november 2005, the content of the Calibration Segment Ntuple has changed, causing a mismatch of ntuple format of what the analysis package expects. This will be repaired before the <font color=red>5th of december </font>.
+
* [[CalibNtupleAnalysis1|CalibNtupleAnalysis-00-00-01]] Capable of processing ntuple format A
 
+
* [[CalibNtupleAnalysis2|CalibNtupleAnalysis-00-00-02]] Capable of processing ntuple format B
The 'old MuonCalib ntuple' contains only patterns, segments and Mdthits (called 'hits'). The 'new MuonCalib ntuple' contains the information given above.
 
 
 
 
 
This package consists of a number of objects:
 
<pre>
 
CalibNtupleAnalysis
 
 
 
                  NTReader                    Reads the ntuple and stores events in Calibration EDM classes
 
                  MuonCalibEvent              Container class for the MuonCalib::MuonGlobalPatterns
 
                  SegmentAnalysis            Steers the analysis performed on the ntuple
 
</pre>
 
 
 
'''Setting up the analysis package'''
 
* go to your work space at your ATLAS account
 
<font color = red><tt> cd 11.0.0/ </tt></font>
 
* get the CalibNtupleAnalysis package (in the future this can be checked out from the release):
 
<font color = red><tt> cp ~zvankest/public/CalibNtupleAnalysis.tgz </tt></font>
 
* and get the hacked MuonSpectrometer/MuonCalib/MuonCalibEventBase package from the same place. This is needed because some incompatibility problems of the MuonCalibEvent class and the MuonGlobalPattern class. In the future this won't be needed, so bear with this for the moment.
 
<font color = red><tt> cp ~zvankest/public/MuonSpectrometer.tgz </tt></font>
 
* unpack the tarred files
 
<font color = red><tt> tar -xvfz <package>.tgz </tt></font>
 
 
 
*An example of an analysis is given in the executable ''exe/Main.cxx''. Try running it after building the package:
 
<font color = red><tt>cd CalibNtupleAnalysis/v*/cmt/</tt>
 
 
 
<tt>cmt config</tt>
 
 
 
<tt>source setup.(c)sh</tt>
 
 
 
<tt>gmake </tt>
 
  
<tt>../i686-slc3-gcc323-opt/Run.exe</tt> </font>
 
 
* After a succesfull Run, you will be provided with the following files:
 
* After a succesfull Run, you will be provided with the following files:
 
<pre>
 
<pre>
 
SegmentAnalysis.root              Containing the Histograms and SegmentDisplays generated by the  
 
SegmentAnalysis.root              Containing the Histograms and SegmentDisplays generated by the  
 
                                   SegmentAnalysis framework. Note that one event may generate over
 
                                   SegmentAnalysis framework. Note that one event may generate over
                                   100 segments.
+
                                   100 SegmentsDisplays.
 
</pre>
 
</pre>
 
'''Customizing your favorite analysis'''
 
'''Customizing your favorite analysis'''
Line 157: Line 94:
 
A skeleton needs some 'meat'... Some example routines will be provided:
 
A skeleton needs some 'meat'... Some example routines will be provided:
 
<pre>
 
<pre>
plotATLAS(MdtCalibSegment*)        Plots the hits on the segment in global coordinates. In the example
+
plotATLAS(MuonCalibSegment*)        Plots the hits on the segment in global coordinates. In the example
 
                                     an extra feature is shown; one can select MDTchambers by stationtype
 
                                     an extra feature is shown; one can select MDTchambers by stationtype
 
                                     with a simple call on the MuonFixedId.
 
                                     with a simple call on the MuonFixedId.
dumpSegment(MdtCalibSegment*)      Dumps MdtCalibSegment information. Invaluable for debugging.
+
dumpSegment(MuonCalibSegment*)      Dumps MdtCalibSegment information. Invaluable for debugging.
refitSegment(MdtCalibSegment)      Refits the MdtCalibSegment with a DCSLFitter provided by the  
+
refitSegment(MuonCalibSegment)      Refits the MdtCalibSegment with a DCSLFitter provided by the  
 
                                     Calibration framework.
 
                                     Calibration framework.
showSegment(MdtCalibSegment*)      Calls a simple eventdisplay in which the hits are drawn as drifcircles
+
showSegment(MuonCalibSegment*)      Calls a simple eventdisplay in which the hits are drawn as drifcircles
 
                                     and the segment as line. The displays can be written to a PSfile.
 
                                     and the segment as line. The displays can be written to a PSfile.
circleResidual(MdtCalibSegment*)    Given the trackparameters and the hits on the segment, this routine
+
circleResidual(MuonCalibSegment*)    Given the trackparameters and the hits on the segment, this routine
 
                                     calculates the expected residuals by extrapolating the track in the
 
                                     calculates the expected residuals by extrapolating the track in the
 
                                     local y-z plane in which the driftradii of the hits are circles.
 
                                     local y-z plane in which the driftradii of the hits are circles.
stripResidual(MdtCalibSegment*)    Given the trackparameters and the hits on the segment, this routine
+
stripResidual(MuonCalibSegment*)    Given the trackparameters and the hits on the segment, this routine
 
                                     calculates the expected residuals by extrapolating the track in the
 
                                     calculates the expected residuals by extrapolating the track in the
 
                                     local x-y plane in which the RPC strips are the precision coordinates.
 
                                     local x-y plane in which the RPC strips are the precision coordinates.
 
</pre>
 
</pre>

Latest revision as of 08:34, 5 December 2005

Muon calibration tutorial

Welcome to the Muon Calibration Tutorial Page! After doing this tutorial, you will be able to run Athena, make your ntuples containing segment information. This ntuple can then be used as input to do analysis with help of the skeleton analysis package provided. This analysis package CalibSegmentAnalysis relies heavily on the Calibration framework but is Athena independent.

Much information on validation, calibration and alignment can be found at the MuonSpectrometer homepage.

Introduction

Calibration

General information about the need of calibration in the MuonSpectrometer.


Calibration framework

A clear Wiki page on the Calibration Framework by Domizia and Niels can be found on the MuonCalibrationFramework Wiki. At this site, the Calibration EDM is explained.


Why segments?

Maybe needed to explain the concept of segments and the calibration EDM, is to be written (work in progress). A starting point of Calibration Segments and its scope in the Reconstruction EDM can be found in a presentation given by Zdenko during the ATLAS Muonweek september-2005 called Calibration Segment Ntuple

Getting started

In order to get started one should know that this field is prone to many changes over time. Backward compatibility is surely broken since the ntuple format changed a lot in the period of november 2005. The ntuple format is defined by the MuonCalib package (MuonCalibNtuple), and the analysis package needs a certain ntuple format to be able to fill the MuonCalib EDM classes offline. In the following sections, recipes will be provided for different kinds of ntuple formats.

To summarize the procedure:

  • Choose your ntuple-format and wich version to run in
  • Follow the recipes below to make your ntuple, customize jobOption file where needed
  • Build the appropriate version of the CalibSegmentAnalysis package (depending on ntuple format)
  • Run your analysis, customize the analyse routine where needed

Different versions of Ntuple Content

Currently, there are two different formats of the Calibration Segment Ntuple, described in the following tables:

  • Calibration Segment Ntuple Content A. Information on patterns, segments en Mdt hits. All segments appear twice on the ntuple since a refit-flag is performed during ntuple-writing. This ntuple should be obsolete since release 11.X.0.
  • Calibration Segment Ntuple Content B. Information on patterns, segments and hits of all technologies (Mdt's containing extra calibration information, the other technologies are not yet fully implemented). No extra refit is performed, so no double segments. In addition, truth information and event information (run and event number) is available.
  • Calibration Segment Ntuple Content C. Is non-existent at the moment. It is sure that one will be defined in the future, the difference with Ntuple Content B will be a better description of the other technology hits, and timing information on event-level.

Which recipe to use to make the Ntuple

The different formats of Ntuples can be produced with different recipes. The following recipes sets up athena and guides you to running the Muon Calibration package. With this running you can proceed to the next section below.

A deeper look into the jobOptions

  • For version 10.5.0: a good example of a jobOptions file that produces segment ntuples is provided in Domizia's public:

cp /afs/cern.ch/user/d/domizia/public/MuonCalib_files/myTopOptions.py .

  • For version 11.0.0: a good example of a jobOptions file that produces segment ntuples is provided in Zdenko's public:

cp /afs/cern.ch/user/z/zvankest/public/MuonCalib_files/myTopOptions.py .

  • you can customize this jobOption file to your own needs...
Change the number of events in the ntuple
Change the tracking software (Moore <-> MuonBoy, and Jochem's cosmic pattern finder package in the future)
Change the muon-sample (note! The file should be present in your PoolFileCatalog):
        in your run directory, add the file to your PoolFileCatalog by calling
              pool_insertFileToCatalog <physical path of your favorite POOL file>
        in your myTopOptions.py, replace the following line
              PoolRDOInput = [ "rfio:/castor/*/*.pool.root" ]
        by
              PoolRDOInput = [ "<POOl file path>" ]

From the ntuple produced, one can proceed Athena-independent.

Segment analysis

A little word about the Calibration Event Data Model (EDM)

The MuonCalibration-framework works with a Calibration EDM, which defines the objects used in the Calibration. The structure is more or less like this:

  • each event contains a certain number of Patterns. Concider these as linked segments, as potential tracks, containing information such as the Chi Squared of the pattern, the track parameters (z0, r0, , , q/p). These patterns are described in the class MuonCalib::MuonGlobalPattern. Patterns are built from a number of segments.
  • a segment is described by MuonCalib::MuonCalibSegment, which is basically a line segment which matches the hits stored in the segment. So segments describe the premature track at chamber level. A line is given by a vector and a direction. This information can be found on the segment as well, in two co-ordinate systems: the global ATLAS co-ordinates and the local chamber co-ordinates.
  • the hits on the segment are implemented as MuonCalib::XxxCalibHitBase 's with Xxx the technology which recorded the hits (i.e. Mdt, Tgc, Csc or Rpc). Each hitBase has their own dedicated content relevant for doing calibration; thus RPCs do not have drifttimes and MDTs do not provide timemeasurements. They do have common members such as (local en global) position and MuonCalib::MuonFixedId 's. Since the Calibration EDM classes are Athena-independent, the identifiers defined for the hit classes are decoupled from the ATLAS data-base (which is Athena-dependent).

In order to do an analysis on segment level from the ntuple, the content from the ntuple must be casted into the Calibration EDM. This can be done with help of a skeleton analysis package.

The CalibNtupleAnalysis package

Since there exists two ntuple formats, different versions of the CalibNtupleAnalysis package exist. Recipes to run the skeleton analysis are given here:

  • After a succesfull Run, you will be provided with the following files:
SegmentAnalysis.root               Containing the Histograms and SegmentDisplays generated by the 
                                   SegmentAnalysis framework. Note that one event may generate over
                                   100 SegmentsDisplays.

Customizing your favorite analysis

A skeleton needs some 'meat'... Some example routines will be provided:

plotATLAS(MuonCalibSegment*)         Plots the hits on the segment in global coordinates. In the example
                                    an extra feature is shown; one can select MDTchambers by stationtype
                                    with a simple call on the MuonFixedId.
dumpSegment(MuonCalibSegment*)       Dumps MdtCalibSegment information. Invaluable for debugging.
refitSegment(MuonCalibSegment)       Refits the MdtCalibSegment with a DCSLFitter provided by the 
                                    Calibration framework.
showSegment(MuonCalibSegment*)       Calls a simple eventdisplay in which the hits are drawn as drifcircles
                                    and the segment as line. The displays can be written to a PSfile.
circleResidual(MuonCalibSegment*)    Given the trackparameters and the hits on the segment, this routine
                                    calculates the expected residuals by extrapolating the track in the
                                    local y-z plane in which the driftradii of the hits are circles.
stripResidual(MuonCalibSegment*)     Given the trackparameters and the hits on the segment, this routine
                                    calculates the expected residuals by extrapolating the track in the
                                    local x-y plane in which the RPC strips are the precision coordinates.