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tuning_the_s800_xdt [2015/10/29 13:21]
pereira [Checking Particle ID and rate at S800 FP] 		tuning_the_s800_xdt [2017/05/26 16:08]
pereira [Timing setup]
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   * Set trigger to “s800 trigger”    * Set trigger to “s800 trigger” 
-      * Ensure that the **[[s800 daq tools#trigger GUI|trigger GUI]]** application is ready. Otherwise, open it by clicking button **[[s800 daq tools#Run Control Window|Launch ULM GUI]]** in ReadoutGUI +      * Ensure that the **[[s800 daq tools#trigger GUI|trigger GUI]]** application is ready. Otherwise, open it by clicking button ''Launch ULM GUI'' in [[#ReadoutGUI|ReadoutGUI]] 
           * Under trigger tab select **s800 trigger** (which is E1 up by definition)           * Under trigger tab select **s800 trigger** (which is E1 up by definition)
           * Deselect experiment trigger           * Deselect experiment trigger
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           * End and Begin **[[s800 daq tools#Run Control Window|ReadoutGUI]]** to assert new trigger condition           * End and Begin **[[s800 daq tools#Run Control Window|ReadoutGUI]]** to assert new trigger condition
  
-  * Select **[[s800 SpecTcl|Spectcl]]** window **S800_SCINT.win** in directory **/user/s800/operations/spectcl/Windows**+  * Select **[[s800 SpecTcl|Spectcl]]** window **S800_SCINT.win** in directory **/user/s800/operations/spectcl/s800v7/Windows**. (NOTE: Spectra definition files can be found in directory **/user/s800/operations/spectcl/s800v7/Definitions**. A good file with useful spectra is **s800xdt.tcl**) 
  
   * Adjust **[[hv bias|bias]]** looking at 2D spectra **e1.deup_e1.dedown** (showing the parameters s800.fp.e1.de_down vs. s800.fp.e1.de_up) for the FP E1 scintillator   * Adjust **[[hv bias|bias]]** looking at 2D spectra **e1.deup_e1.dedown** (showing the parameters s800.fp.e1.de_down vs. s800.fp.e1.de_up) for the FP E1 scintillator
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-  * Select **[[s800 SpecTcl|Spectcl]]** window **S800_IC.win** in directory **/user/s800/operations/spectcl/Windows** +  * Select **[[s800 SpecTcl|Spectcl]]** window **S800_IC.win** 
  
   * Adjust pad gains   * Adjust pad gains
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       * Count rate is a little higher than on scintillator due to noise or thresholds       * Count rate is a little higher than on scintillator due to noise or thresholds
  
-  * Check **[[s800 SpecTcl|Spectcl]]** window **S800_CRDCS.win** in directory **/user/s800/operations/spectcl/Windows** (see figure below) to verify the good performance of the detectors. (The spectra for each CRDC can be checked separatelly in windows **s800_CRDC1.win** and **S800_CRDC2.win**)+  * Check **[[s800 SpecTcl|Spectcl]]** window **S800_CRDCS.win** (see figure below) to verify the good performance of the detectors. (The spectra for each CRDC can be checked separatelly in windows **s800_CRDC1.win** and **S800_CRDC2.win**)
  
       * Spectra **crdc1.raws** and **crdc2.raws** (top and middle spectra in the leftmost (first) column)       * Spectra **crdc1.raws** and **crdc2.raws** (top and middle spectra in the leftmost (first) column)
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       * The two spectra in the fifth row corresponds to the MTDC summary spectra of OBJ-FP and XFP-FP ToFs (zoomed in). The spectra show the ToF (vertical axis) vs. hit number (horizontal axis). Note that in a unreacted-beam setting, the first hit typically provides the "good" ToF (i.e. start and stop signals come from the same event). This is not the case in a reaction setting, where the rates in the XFP and OBJ detectors are much higher than in the FP SCI        * The two spectra in the fifth row corresponds to the MTDC summary spectra of OBJ-FP and XFP-FP ToFs (zoomed in). The spectra show the ToF (vertical axis) vs. hit number (horizontal axis). Note that in a unreacted-beam setting, the first hit typically provides the "good" ToF (i.e. start and stop signals come from the same event). This is not the case in a reaction setting, where the rates in the XFP and OBJ detectors are much higher than in the FP SCI 
       * An empty ToF spectrum means that either the delays are not right (and need to be adjusted) or the spectrum range is too narrow        * An empty ToF spectrum means that either the delays are not right (and need to be adjusted) or the spectrum range is too narrow 
-      * The MTDC spectra should never be empty because the matching window is sufficiently wide (around 4000 ns)+      * The MTDC delays should never need to be adjusted because the matching window is sufficiently wide (around 4000 ns)
  
 {{:wiki:SpecTcl-e14019-run103.jpg?850|S800_ToF.win page}} {{:wiki:SpecTcl-e14019-run103.jpg?850|S800_ToF.win page}}
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   * Due to the multi-hit capability of the MTDC, we need to select the "good" MTDC ToF peak so that SpecTcl can search for the right hit (more details can be found [[Timing#MTDC|here]]):   * Due to the multi-hit capability of the MTDC, we need to select the "good" MTDC ToF peak so that SpecTcl can search for the right hit (more details can be found [[Timing#MTDC|here]]):
       * Use the spectra **TOF.MTDC_RF**, **TOF.MTDC_OBJ**, and **TOF.MTDC_XFP** (second row in figure above)        * Use the spectra **TOF.MTDC_RF**, **TOF.MTDC_OBJ**, and **TOF.MTDC_XFP** (second row in figure above) 
-      * Using the cursor mouse, check the lower and higher limits defining the region in the MTDC ToF spectra with the "good" ToF peak. Do it of the three ToFs: RF-FP, OBJ-FP, and XFP-FP+      * Using the cursor mouse, check the lower and higher limits defining the region in the MTDC ToF spectra with the "good" ToF peak. Do it for the three ToFs: RF-FP, OBJ-FP, and XFP-FP
       * Go to the **Variables** page in SpecTcl GUI and assign the limits to the following variables:        * Go to the **Variables** page in SpecTcl GUI and assign the limits to the following variables: 
-              * s800.fp.vmetdc.mtdc_objlow and s800.fp.vmetdc.mtdc_rfhigh for RF-XFP +              * **s800.fp.vmetdc.mtdc_rflow** and **s800.fp.vmetdc.mtdc_rfhigh** for RF-XFP 
-              * s800.fp.vmetdc.mtdc_objlow and s800.fp.vmetdc.mtdc_rfhigh for OBJ-XFP +              * **s800.fp.vmetdc.mtdc_objlow** and **s800.fp.vmetdc.mtdc_objhigh** for OBJ-XFP 
-              * s800.fp.vmetdc.mtdc_xfplow and s800.fp.vmetdc.mtdc_xfphigh for XFP-XFP+              * **s800.fp.vmetdc.mtdc_xfplow** and **s800.fp.vmetdc.mtdc_xfphigh** for XFP-XFP
       * For each ToF, SpecTcl will search the hit number that fits in the selected region. The new MTDC ToF parameters are **s800.fp.vmetdc.mtdc_rf**, **s800.fp.vmetdc.mtdc_obj**, and **s800.fp.vmetdc.mtdc_xfp**        * For each ToF, SpecTcl will search the hit number that fits in the selected region. The new MTDC ToF parameters are **s800.fp.vmetdc.mtdc_rf**, **s800.fp.vmetdc.mtdc_obj**, and **s800.fp.vmetdc.mtdc_xfp** 
  
-  * If necessary, adjust delays: +  * If necessary, adjust delays of Phillips TDC (in principle, the TACs delays don't need to be adjusted)
-      * Using the [[S800 DAQ tools#Trigger GUI|ULM trigger GUI]] assign TDC-start to one of the Inspect Trigger channels and trigger the scope with it +      * Using the [[S800 DAQ tools#Trigger GUI|ULM trigger GUI]] assign TDC-start to one of the Inspect Trigger channels (patch panel #55 - #58) and trigger the scope with it (be aware that the TDC-start signal seen in the scope has an additional delay of ~200 ns due to the length of the cables between the ULM module in S3 vault and dataU6 patch panel) 
-      * Select the timing signals (Delay inspect channels) E1 up, OBJ and XFP with the [[S800 DAQ tools#Delay Window|Delay GUI]] and look at them in the scope +      * Connect the XFP and/or OBJ signals going to the Phillips TDC (via cables plugged to patch #66 and #67, respectively) to the scope 
-      * Adjust the TDC delays of OBJ and XFP using the delay boxes connected to the CANBERRA CFD 454 in data U6 +      * Adjust the TDC delays of OBJ and/or XFP with respect to the TDC start, using the delay boxes connected to the CANBERRA CFD 454 in data U6 
-      * Adjust the TDC delays of E1 updown using the Delay GUI +      * Be aware that the after adjusting OBJ and XFP delays in the scope, the signal will be further delayed by ~200 ns due to the length of the cable between dataU6 patch panel and the Phillips TDC in the S3 vault. 
-      * In principle, the TACs delays don't need to be adjusted+      * Check the corresponding ToF spectra in SpecTcl to confirm that the timings are properly adjusted
 + 
 +  * Check the efficiencies of the Phillips TDC, TACs, and MTDC for the OBJ-FP and XFP-FP ToFs: 
 +      * Make a gate on spectrum **IC.SUM** selecting the region of interest, and call it "IC" 
 +      * Looking at the ToF spectra gated on "IC" compare the recorded events in the spectra with the number of events in the gate 
 +      * The window file **S800_TOF_EFFICIENCY.win** includes all the spectra needed 
  
 ==== Checking Particle ID and rate at S800 FP ==== ==== Checking Particle ID and rate at S800 FP ====
  
-  * Select SpecTcl window **S800_PID.win** in directory **/user/s800/operations/spectcl/s800v7/Windows** +  * Select SpecTcl window **S800_PID.win** 
       * The three columns correspond to the PID determined with the **RF-FP** ToF (left), **OBJ-FP** (center), and **XFP-FP** (right)       * The three columns correspond to the PID determined with the **RF-FP** ToF (left), **OBJ-FP** (center), and **XFP-FP** (right)
       * The first (top) row corresponds to PID spectra using the Phillips TDC       * The first (top) row corresponds to PID spectra using the Phillips TDC
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   * Set trigger to “s800 trigger”   * Set trigger to “s800 trigger”
-      * Ensure that the **[[s800 daq tools#trigger GUI|trigger GUI]]** application is ready. Otherwise, open it by clicking icon **[[s800 daq tools#Run Control Window|RunControl]]** in the desktop of [[Software#u6pc5 (data U6)|u6pc5]] computer+      * Ensure that the **[[s800 daq tools#trigger GUI|trigger GUI]]** application is ready. Otherwise, open it by clicking ''Launch ULM GUI'' on [[#Readout GUI|Readout GUI]] in the desktop of [[Software#u6pc5 (data U6)|u6pc5]] computer
       * Under trigger tab select **s800 trigger** (which is E1 up by definition)       * Under trigger tab select **s800 trigger** (which is E1 up by definition)
           * Deselect experiment trigger           * Deselect experiment trigger
           * SAVE TO FILE           * SAVE TO FILE
-          * Stop and start **[[s800 daq tools#Run Control Window|RunControl]]** to assert new trigger condition+          * Begin a new run on [[#Readout GUI|Readout GUI]]  to assert new trigger condition
  
   * Select **[[s800 SpecTcl|Spectcl]]** window **S800_DISPMATCH.win**   * Select **[[s800 SpecTcl|Spectcl]]** window **S800_DISPMATCH.win**
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               * What experimenters want (e.g., if they want singles, the cut has to be more restrictive to limit acquisition deadtime)               * What experimenters want (e.g., if they want singles, the cut has to be more restrictive to limit acquisition deadtime)
           * Move blocker, decrease attenuator, repeat           * Move blocker, decrease attenuator, repeat
 +
 +      * If necessary, do the ToF corrections to improve the PID resolution (instructions [[During experiments#Particle identification corrections|here]])
  
  
tuning_the_s800_xdt.txt · Last modified: 2023/09/22 15:15 by swartzj

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