Difference between revisions of "DeltaDoverD Progress"

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   i.) Calculate absolute cross section for Cos Thet_pi = 0.5,  1 < Q^2 < 4 GeV^2  , W = 1.45 +/- 0.2 GeV
 
   i.) Calculate absolute cross section for Cos Thet_pi = 0.5,  1 < Q^2 < 4 GeV^2  , W = 1.45 +/- 0.2 GeV
  
[[Image:phi_angle_in_CM_Frame_vs_Relative_Rate_cos_theta_0-4_0-6_W_1-45.jpg|200px]]  
+
[[Image:phi_angle_in_CM_Frame_vs_Relative_Rate_cos_theta_0-4_0-6_W_1-45.jpg|400px]]  
  
 
   ii.) Plot <math>\phi_{diff}^{CM}</math>-vs-<math>cos{\theta}_{\pi}^{LAB}</math> when <math>cos{\theta}_{e}^{CM}</math> = -0.3  also plot <math>\phi_{diff}^{CM}</math>-vs- <math>cos{\theta}_{e}^{LAB}</math>
 
   ii.) Plot <math>\phi_{diff}^{CM}</math>-vs-<math>cos{\theta}_{\pi}^{LAB}</math> when <math>cos{\theta}_{e}^{CM}</math> = -0.3  also plot <math>\phi_{diff}^{CM}</math>-vs- <math>cos{\theta}_{e}^{LAB}</math>

Revision as of 22:39, 15 September 2008

9/5/08

1.) SIDIS Analysis

a.) Cross-Section comparison

 Figure out the definition of cross-section being used in the data
 i.) Calculate absolute cross section for Cos Thet_pi = 0.5,  1 < Q^2 < 4 GeV^2  , W = 1.45 +/- 0.2 GeV

Phi angle in CM Frame vs Relative Rate cos theta 0-4 0-6 W 1-45.jpg

 ii.) Plot [math]\phi_{diff}^{CM}[/math]-vs-[math]cos{\theta}_{\pi}^{LAB}[/math] when [math]cos{\theta}_{e}^{CM}[/math] = -0.3  also plot [math]\phi_{diff}^{CM}[/math]-vs- [math]cos{\theta}_{e}^{LAB}[/math]
electron sector pion_theta_angle_vs_phi_angle_in_CM_Frame_after_cuts(EC_inner>0.06, EC_tot/p>0.2, nphe>2.5, [math]0.9\lt M_x\lt 1.1[/math], [math]1.1\lt W\lt 1.5[/math] ) electron_theta_angle_vs_phi_angle_in_CM_Frame_after_cuts(EC_inner>0.06, EC_tot/p>0.2, nphe>2.5, [math]0.9\lt M_x\lt 1.1[/math], [math]1.1\lt W\lt 1.5[/math] )
1 Pion theta angle vs phi angle in cm frame after cuts e sector 1.gif Electron theta angle vs phi angle in cm frame after cuts e sector 1.gif
2 Pion theta angle vs phi angle in cm frame after cuts e sector 2.gif Electron theta angle vs phi angle in cm frame after cuts e sector 2.gif
3 Pion theta angle vs phi angle in cm frame after cuts e sector 3.gif Electron theta angle vs phi angle in cm frame after cuts e sector 3.gif
4 Pion theta angle vs phi angle in cm frame after cuts e sector 4.gif Electron theta angle vs phi angle in cm frame after cuts e sector 4.gif
5 Pion theta angle vs phi angle in cm frame after cuts e sector 5.gif Electron theta angle vs phi angle in cm frame after cuts e sector 5.gif
6 Pion theta angle vs phi angle in cm frame after cuts e sector 6.gif Electron theta angle vs phi angle in cm frame after cuts e sector 6.gif


[math]0\lt cos{\theta}_{\pi}^{LAB}\lt 32[/math]


Pion theta vs phi angle cm Theta pion lab 0 32 3D.gifPhi angle cm Theta pion lab 0 32 3D.gif

[math]Q^2[/math]_vs_[math]\phi_{diff}^{CM}[/math] plot

Q sqrd vs phi angle in cm frame after cuts all Q.gif


2.) Detector Construction

   4 chambers are built.   
TGEM:
Foils have been mounted on the TGEM comparison chamber.  Both charge collectors are mounted on the TGEM test detectors.  One TGEM test detector has the Thick PC board GEM foils which need much higher HV than the regular GEM foils.  The second TGEM test chamber has 3 GEM foils from CERN.

Need a min of 32 1 Meg Ohm resistors to complete the output termination connectors. Need 32 more termination connectors made from 16 wires.

Need to grind down 16, M3 bolts for mounting the GEM foils and TGEM PCboards.

Need 24 washers for GEM foils. Check mounting of the TGEM boards. Look up spacing and HV for the TGEM boards[1], Media:01352098.pdf .

Need to etch 2 cathodes for the TGEm boards.


Qweak:

  a.) Need to do final outer footprint machining so there is no interference with the Electron profile of the other octant.
  b.)  Need to machining back of the chamber for the Charge collector
 c.) Need to machine thick frames for the cathode and maybe GEM foils.
 d.) Apply electrical insulation to HV distribution boards
 e.) Need to mount GEM foils on the Qweak chambers.

3.) SIS3610 I/O software

Objectives: a.) The first step will be to read 16 of the I/O input channel into a CODA data file.

b.) Display the 16 input channels on a GUI. Unfortunately, only 2 of the 16 will be used to read in the GEM output. The GEM output will transfer 128 hit/no hit signals to a single I/O channel in a serial fashion. The data from one I/O channel needs to be decoded according to the data structure described in Figure 8 and 9 of the VFAT manual.

c.) The final task will be to write a multiple trigger function so the I/O can be triggered by several different interrupt trigger signals and label those trigger signals.


Tasks:

Inject a signal into the I/O board input connector and use a Read function from the ROC to determine if the signal is high or low.


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