Qweak R1 Software
Slow Control GUI
MEDM
use EPICS se set HV channels and alarms
Lab View
rotation control.
VFAT setup
The VFAT setup is done through a web interface.
GEM data processing
The GEM detector contains 6 VFAT cards which are used to digitize the charge from an ionization event. Each channel of the VFAT is associated with a charge collection strip within the GEM ionization chamber. Once triggered the VFAT card will transfer 192 bits (Defined in Figure 8 of the VFAT manual V2.0) from each VFAT card to separate I/O channels on a CAEN V1495 module.
VFAT to V1495
V1495 to CODA data file
CODA file to Tracking data structure
A ROC will transfer GEM data from a CAEN V1495 to the host DAQ computer. At the local institution there will only be one element of the Qweak tracking software. Once the ROC is writeing data to a CODA file from the V1495 we will need to write software which will take the raw data and create a data structure for tracking. The data structure for tracking, in the case of R1, will contain the distance of the elastic scattering event from the beam pipe center () and representing the local polar angle in which at the center of the detector.
The SVN repository for the Qweak Analysis and tracking software is at
https://qweaksvn.jlab.org/repos/QwAnalysis/trunk/Analysis
Qweak wiki describing the software is at
https://qweak.jlab.org/wiki/index.php/Installation_and_compilation
GEM data header file is located in
QwAnalysis/ Tracking/include/QwGasElectronMultiplier.h
The above defines the processed data structure, it includes a ProcessEventBuffer function to strip data out of the raw CODA data buffer, defines the function to create a QwHit for each r and phi strip hit
Int_t ProcessConfigurationBuffer(const UInt_t roc_id, const UInt_t bank_id, UInt_t* buffer, UInt_t num_words){return 0;}; /* contains IPreamp info if needed occurs during Prestart*/
Int_t ProcessEvBuffer(UInt_t roc_id, UInt_t bank_id, UInt_t* buffer, UInt_t num_words){return 0;};/* filters out VFAT data from CODA bank*/
void ProcessEvent() /* fills hit list */
QwGasElectronMultiplier->fHits
create a tracking source file in the subdirectory which contains the actual code to do the above
QwAnalysis/Tracking/src/QwGasElectronMultiplier.cc
The above *.cc file also needs a LoadMap function to read a prminput file (located in Tracking/prminput/)
an example of which is shown in
Tracking/src/QwDriftChamber.cc
Int_t QwDriftChamber::LoadChannelMap(TString mapfile){
TString varname, varvalue;
UInt_t chan, package, plane, wire, direction, DIRMODE;
DIRMODE=0;
fDirectionData.resize(2);//currently we have 2 package - Rakitha (10/23/2008)
fDirectionData.at(0).resize(12); //currently we have 12 wire planes in each package - Rakitha (10/23/2008)
fDirectionData.at(1).resize(12); //currently we have 12 wire planes in each package - Rakitha (10/23/2008)
QwParameterFile mapstr(mapfile.Data()); //Open the file
while (mapstr.ReadNextLine()){
mapstr.TrimComment('!'); // Remove everything after a '!' character.
mapstr.TrimWhitespace(); // Get rid of leading and trailing spaces.
if (mapstr.LineIsEmpty()) continue;
Another simpler eaxample is in
Tracking/src/QwMainDetector.cc
Int_t QwMainDetector::LoadChannelMap(TString mapfile){
TString varname, varvalue;
TString modtype, dettype, name;
Int_t modnum, channum;
QwParameterFile mapstr(mapfile.Data()); //Open the file
while (mapstr.ReadNextLine()){
mapstr.TrimComment('!'); // Remove everything after a '!' character.
mapstr.TrimWhitespace(); // Get rid of leading and trailing spaces.
if (mapstr.LineIsEmpty()) continue;
if (mapstr.HasVariablePair("=",varname,varvalue)){
// This is a declaration line. Decode it.
varname.ToLower();
UInt_t value = atol(varvalue.Data());
if (varname=="roc"){
RegisterROCNumber(value);
} else if (varname=="bank"){
RegisterSubbank(value);
} else if (varname=="slot"){
DataBase info
The following run-by-run information should be included in a database table
Two tables:
R1G1 = Region 1 GEM Detector 1 R1G2 = Region 1 GEM Detector 1
Each of the 2 tables has 2 High Voltage entries, an Octant location, and 6 sub tables one for each VFAT electronics card
HVdrift HVGEM Octant VFATChipID_A VFATChipID_B VFATChipID_C VFATChipID_D VFATChipID_E VFATChipID_F
Each of the 6 electronics cards (VFATChip_ID) above have the following information
IPreampIn IPreampFeed IPreampOut IShaper IShaperFeed IComp UpsetReg Lat VThreshold1 VThreshold2
In addition to the above variables each chip has 128 Channels which can contain TrimDAC offsets and a mask
ChanReg_1_Mask ChanReg_1_TrimDAC ChanReg_2_Mask ChanReg_2_TrimDAC ChanReg_3_Mask ChanReg_4_TrimDAC
....
ChanReg_128_Mask ChanReg_128_TrimDAC
At the end of a tracking run each of the above chips will have "scaler" counts recorded with the following names
HitCount0 HitCount1 HitCount2
Monitoring Histograms GUI
Hit display
References