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A quick walk-through of the tools that exist for analysis of xtc files with python.
The main focus is on pyana, and the examples are from and for XPP primarily,
but may be useful examples to other experiments too.
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The Basics
Python
http://docs.python.org/tutorial/
Pyana
Analysis Workbook. Python-based Analysis
Exploring an xtc file
pyxtcreader
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pyxtcreader -h usage: pyxtcreader [options] xtc-files ... options: -h, --help show this help message and exit -v, --verbose -l L1_OFFSET, --l1-offset=L1_OFFSET |
Loops through the xtc datagrams and dumps info to screen. I recommend piping it to 'less'.
xtcscanner
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xtcscanner -h usage: xtcscanner [options] xtc-files ... options: -h, --help show this help message and exit -n NDATAGRAMS, --ndatagrams=NDATAGRAMS -v, --verbose -l L1_OFFSET, --l1-offset=L1_OFFSET -e, --epics |
Similar to pyxtcreader in that it loops throug xtc datagrams, but doesn't print to screen. Internally counts the datatypes it finds, and at the end dumps a summary only. Optinally prints out epics information (default no).
Example output:
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xtcscanner /reg/d/psdm/xpp/xppi0310/xtc/e81-r0098-s0* Scanning.... Start parsing files: ['/reg/d/psdm/xpp/xppi0310/xtc/e81-r0098-s00-c00.xtc', '/reg/d/psdm/xpp/xppi0310/xtc/e81-r0098-s01-c00.xtc'] 14826 datagrams read in 4.120000 s . . . . . . . ------------------------------------------------------------- XtcScanner information: - 61 calibration cycles. - Events per calib cycle: [240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240, 240] Information from 1 control channels found: fs2:ramp_angsft_target Information from 11 devices found BldInfo:EBeam: EBeamBld_V1 (14641) BldInfo:FEEGasDetEnergy: FEEGasDetEnergy (14563) Any (78) BldInfo:NH2-SB1-IPM-01: SharedIpimb (14641) BldInfo:PhaseCavity: PhaseCavity (14641) DetInfo:EpicsArch-0|NoDevice-0: Epics_V1 (107580) DetInfo:NoDetector-0|Evr-0: EvrConfig_V4 (62) EvrData_V3 (14640) DetInfo:XppSb2Ipm-1|Ipimb-0: IpimbConfig_V1 (1) IpmFexConfig_V1 (1) IpimbData_V1 (14640) IpmFex_V1 (14640) DetInfo:XppSb3Ipm-1|Ipimb-0: IpimbConfig_V1 (1) IpmFexConfig_V1 (1) IpimbData_V1 (14640) IpmFex_V1 (14640) DetInfo:XppSb3Pim-1|Ipimb-0: IpimbConfig_V1 (1) IpmFexConfig_V1 (1) IpimbData_V1 (14640) IpmFex_V1 (14640) DetInfo:XppSb4Pim-1|Ipimb-0: IpimbConfig_V1 (1) IpmFexConfig_V1 (1) IpimbData_V1 (14640) IpmFex_V1 (14640) ProcInfo:: RunControlConfig_V1 (62) XtcScanner is done! ------------------------------------------------------------- |
xtcexplorer
XTC Explorer - GUI interface that builds pyana modules for you.
Extracting the data with pyana, some examples
Outline of a pyana module
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Point detector delay scan
- Fetching the ControlPV information:
ControlPV is available from theenv
object, and since it only changes at the beginning
of each calibration cycle, thebegincalibcycle
function is the appropriate place to get it:Code Block none none def begincalibcycle( self, evt, env ) :
The ControlConfig object may contain several pvControl and pvMonitor objects. In this case
there's only one, but make sure the name matches anyway:Code Block none none ctrl_config = env.getConfig(TypeId.Type.Id_ControlConfig) for ic in range (0, ctrl_config.npvControls() ): cpv = ctrl_config.pvControl(ic) if cpv.name()=="fs2:ramp_angsft_target": # store the value in a class variable (visible in every class method) self.current_pv_value = cpv.value() )
- Fetching the IPIMB and PhaseCavity information:
All the other information that we need, is available through theevt
object, and
event
member function is the place to get it:Code Block none none def event( self, evt, env ) :
Use "XppSb3Ipm-1|Ipimb-0" (a.k.a. IPM3) sum of all channels for normalization and filteringCode Block none none ipmN_raw = evt.get(TypeId.Type.Id_IpimbData, "XppSb3Ipm-1|Ipimb-0") ipmN_fex = evt.get(TypeId.Type.Id_IpmFex, "XppSb3Ipm-1|Ipimb-0") ipmN_norm = ipmN_fex.sum
Use "XppSb3Pim-1|Ipimb-0" (a.k.a. PIM3) channel 1 as signalCode Block none none ipmS_raw = evt.get(TypeId.Type.Id_IpimbData, "XppSb3Pim-1|Ipimb-0" ) ipmS_fex = evt.get(TypeId.Type.Id_IpmFex, "XppSb3Pim-1|Ipimb-0" ) ipm_sig = ipmS_fex.channel[1]
Get the phase cavity:Code Block none none pc = evt.getPhaseCavity() phasecav1 = pc.fFitTime1 phasecav2 = pc.fFitTime2 charge1 = pc.fCharge1 charge2 = pc.fCharge2
Compute delay time and fill histogramsCode Block none none delaytime = self.current_pv_value + phasecav1*1e3 # The "histograms" are nothing but python lists. Append to them, and turn them into arrays at the end. self.h_ipm_rsig.append( ipm_sig ) self.h_ipm_nsig.append( ipm_sig/ipm_norm ) self.h_delaytime.append( delaytime )
Image peak finding
CSPad images and tile arangements
Saving data arrays
Plotting with MatPlotLib
Interactive analysis with iPython
Non-interactive batch analysis
Overview
Content Tools