9/5/08

SIDIS Analysis

a.) Cross-Section comparison

i.) Calculate absolute cross section for [math]\cos(\theta_{pi})[/math] = 0.5, 1 < Q^2 < 4 GeV^2 , W = 1.45 +/- 0.2 GeV

[math]{\sigma} = \frac{1}{ L_{int}}dN = \frac{35}{3.3 \times 10^{34}} \times cm^2 = 10.61 \times10^{-34} \times 10^{24} \times [barn] = 1.061 \times 10^{-3} [\mu barn][/math]

Luminosity Calculation

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]

As one can see from histograms of the pion_theta_angle_vs_phi_angle_in_CM_Frame and the electron_theta_angle_vs_phi_angle_in_CM_Frame, the pion and electron acceptance in the region of [math]\phi_{diff}^{CM}=180[/math] is nearly zero(significantly low).

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
2
3
4
5
6

[math]Q^2[/math]_vs_[math]\phi_{diff}^{CM}[/math] plot shows that the [math]Q^2[/math] cut should not make much difference on [math]\phi_{diff}^{CM}[/math] plot. The cut around [math]1 GeV^2 \lt Q^2\lt 2 GeV^2[/math] should reduce the number of pions around 0 and 360 of phi angle.

9/19/08

SIDIS Analysis

a.) Cross-Section comparison

i.) Calculate absolute cross section for [math]\cos(\theta_{pi})[/math] = 0.5, 1 < Q^2 < 4 GeV^2 , W = 1.45 +/- 0.2 GeV

[math]\frac{d \sigma}{d \Omega^*_{\pi}} = \frac{1.061 \times 10^{-3} [\mu barn]}{0.88} = 0.0012 \ne 2.4[/math]?

Documentation

The five-fold differential cross section for single pion production is equal to the following:

[math]\frac{\partial^5 \sigma}{\partial E_f \partial \Omega_e \partial {\Omega_{\pi}}^*} = \frac{1}{2 \pi} \Sigma \frac{1}{L_{int} A_{cc} \epsilon_{CC} \Delta W \Delta Q^2 \Delta cos {\theta_{\pi}}^* {\phi_{\pi}}^*} \frac{d(W, Q^2)}{d(E_f, cos \theta_e)}[/math]

The Jacobian term can be given as:

[math]\frac{d(W, Q^2)}{d(E_f, cos \theta_e)} = \frac{2 M_p E_i E_f}{W}[/math]

[math]\frac{\partial^5 \sigma}{\partial E_f \partial \Omega_e \partial {\Omega_{\pi}}^*} = \Gamma_{v}\times \frac{d^2 \sigma}{d {\Omega_{\pi}}^*}[/math]

where [math]\Gamma_{v}[/math] is the virtual photon flux and can be written as

[math]\Gamma_{v} = \frac{\alpha}{2 \pi^2 Q^2} \frac{(W^2 - {M_p}^2)E_f}{2M_p E_e} \frac{1}{1-\epsilon}[/math]

[math]\epsilon = (1 + 2(1+\frac{{\nu}^2}{Q^2})tan^2 \frac{\theta_e}{2})^{-1}[/math]

The reason of having low cross section might be binning

In paper they use the following number of bins:

Number of bins in my case were 360.

Number of bins equal is ~24

When i applied [math]1.6\lt Q^2\lt 1.84[/math] cut, the number of entries were reduced to 152.

In paper they use liquid-hydrogen unpolarized target(we have NH3 and ND3 polarized). The polarized electron beam current is 8 nA(in our case it is about 6 nA). and luminosity is different too. It also depends on statistics.

ii.) What is smallest angular coverage of EC (8 degrees?) Determine phi region where there is no acceptance ( where should we stop plotting data)?

iii.) Asymmetry Calculation

a.) Beam Asymmetry Plot

In order to plot Beam Asymmetry we need to plot for the first time the histogram of the invariant_mass_vs_cross_section. Then determine the structure function fitting the cross section and calculating the beam asymmetry function which is given as :

[math]A_{TL^'} = \sqrt{2\epsilon (1 - \epsilon)} \sigma_{LT^'} \times sin{\phi_{\pi}}^*[/math]

for given cos(theta) of the pion in cm, Q^2 and W invariant mass.

Choose kinematics ( a single theta and phi point )to max our stats and comparison to paper Histogram the following

1. Number of e-pi coincidence events, number of FC counts
2. Number of e-pi coincidence events/FC counts
3. Number of e-pi coincidence events/FC count/Pt

for groups of runs with h_e,P_t = ++, +-, -+, --

table with 4 columns of h_e, P_t and 3 rows of the above histograms

9/26/08

SIDIS Analysis

1.) make semi-inclusive spectrum:

a.) h>0 Pt>0 b.) h > 0 pt<0 c.)h<0 pt>0 d.)h<0 pt<0

2.) ad up opposite target polarization histograms

3.) subtract h> 0 and h<0

helflag = 1 =>

helflag = 2 =>

helflag = 3 =>

helflag = 4 =>

Phi_angle_CM vs Asymmetry

Compared data(there is no table for asymmetry values like cross section):

11/21/08

0.) insert run summarry table, Pb, Pt, PB*Pt, Btorus

1.) make semi-inclusive spectrum:

a.) h>0 Pt>0

b.) h > 0 pt<0

c.)h<0 pt>0

d.)h<0 pt<0

2.) helicity difference plots for Pt>0 and Pt<0

3.) Asym plots for Pt>0 and Pt< 0

4.) unpolarized target asymmetry

Rebin asymmetry hisograms and combine the two into a total asymmetry histogram

Run Summary Table

The table below should have run ranges with 
[math]P_b*P_t \pm \Delta (P_b *P_t)[/math] according 
to the elastic asymmetry measurements stored at
http://www.jlab.org/Hall-B/secure/eg1/EG2000/eg1b_analysis_progress.htm.

http://www.jlab.org/Hall-B/secure/eg1/EG2000/josh/pbpt/

5.73 in
pos = 0.45743 +/- 0.04269
neg = -0.38816 +/- 0.04556

5.73 out
pos = 0.46604 +/- 0.03496
neg = -0.50684 +/- 0.03578

Phi_Angle_CM_Frame for Positive and Negative Target Polarization

Helcode #	Negative Target Polarization	Positive Target Polarization
1 h>0
2 h<0
3
4

Helicity Difference Plots for Pt>0 and Pt<0

Helicity Difference	Negative Target Polarization	Positive Target Polarization
h1-h4
h3-h2

5-01-2009

Target and Beam Polarization are positive

Helcode #	Negative Beam Torus	Positive Beam Torus
1 h>0
2 h<0
3
4

Target Polarization Positive and Beam Polarization Negative

Helcode #	Negative Beam Torus	Positive Beam Torus
1 h>0	No Data
2 h<0	No Data
3	No Data
4	No Data

Inclusive Histograms For Invariant Mass

Invariant Mass Histograms for Each Sector

All helicities

Helcode=1

3/20/09

1.) plot Wdiff

2.) plot PE using Osipenko/Josh cuts

06/6/09

Invariant Mass

Difference of Invariant Mass for two differnet cuts:

Run Number	EC Cuts+ requiring pion	OSI Cuts	EC Cuts
26991

On x-axis of FC difference between the "+" heliciy FC  and the "-" helicity FC.

Run Number	W difference	FC difference	End of Run sum [math]\equiv \frac {\sum_i(FC(i)^+) - \sum(FC(i)^-)}{\sum (FC(i)^+) + \sum(FC(i)^-)})[/math]
26991		150px	0.00354260538 [math]\pm[/math] 0.00001050400
26994			0.00367 [math]\pm[/math] 0.00001088263
26993			0.002559223 [math]\pm[/math] 0.00001120796
26992			0.003781[math]\pm[/math]0.00001090044
26990			0.00331986321[math]\pm[/math]0.00001203387
26989			0.00303841557[math]\pm[/math]0.00001267152
26988			0.00380169243[math]\pm[/math]0.00001097470
26987			0.00280163240[math]\pm[/math]0.00001515270
26986			0.00352882616[math]\pm[/math]0.00000048897
26979			-0.00373104126[math]\pm[/math]0.00001531706
26965			0.00454140439[math]\pm[/math]0.00001534923
26964			0.00509434283 [math]\pm[/math]0.00001557226
26963			0.00405285155 [math]\pm[/math]0.00001575049
26961			0.00507456102 [math]\pm[/math]0.00001682744
26959			0.00523761694 [math]\pm[/math]0.00001488890
26958			0.00444205478 [math]\pm[/math] 0.00001577510
26956			0.00504401620 [math]\pm[/math]0.00001565456
26955			0.00559913829 [math]\pm[/math]0.00001425736
26954			0.00494690728 [math]\pm[/math]0.00001443107
26953			0.00562598448 [math]\pm[/math]0.00001525797
26952			0.00485295834 [math]\pm[/math]0.00001293033
26951			0.00545485906 [math]\pm[/math]0.00001558637
26947			0.00465697160 [math]\pm[/math]0.00001144285
26945			-0.00556456389 [math]\pm[/math] 0.00001389870
26943			-0.00656109472 [math]\pm[/math]0.00001540342
26942			-0.00669169106 [math]\pm[/math]0.00001526771
26941			-0.00676460417 [math]\pm[/math]0.00001100372
26940			-0.00643597022 [math]\pm[/math]0.00001397207
26939			-0.00650047456 [math]\pm[/math]0.00001405001
26938			-0.00632630313 [math]\pm[/math]0.00001411839
26937			-0.00533169794 [math]\pm[/math]0.00001417768
26934			-0.00601497156 [math]\pm[/math]0.00001422560
26933			-0.00586540500 [math]\pm[/math]0.00001414938
26932			-0.00587687192 [math]\pm[/math]0.00001383218
26931			-0.00630232566 [math]\pm[/math]0.00001495053
26930			-0.00684205010 [math]\pm[/math]0.00001541629
26929			-0.00521666944 [math]\pm[/math]0.00001555256
26928			-0.00682185316 [math]\pm[/math]0.00001536552
26927			-0.00599647483 [math]\pm[/math]0.00001538040
26926			-0.00649932378 [math]\pm[/math]0.00001302331
26925			-0.00575464099 [math]\pm[/math]0.00001530219
27079			-0.01025869470 [math]\pm[/math]0.00002322298
27078			-0.01128036266 [math]\pm[/math]0.00002135573
27075			-0.01037443017 [math]\pm[/math]0.00002113646
27109			-0.00876887465 [math]\pm[/math] 0.00000232599
27107			0.01044530752 [math]\pm[/math] 0.00000191625
27116			0.00173242954 [math]\pm[/math] 0.00000380546
27112			-0.01142682761 [math]\pm[/math] 0.00000251199
27111			-0.00872760886 [math]\pm[/math] 0.00000179327
27128			0.00193441756 [math]\pm[/math] 0.00000189649
27127			0.00215712098 [math]\pm[/math] 0.00000191150
27124			0.00309070808 [math]\pm[/math] 0.00000199918
27139			-0.00288862444 [math]\pm[/math] 0.00000288144
27138			-0.00061608634 [math]\pm[/math] 0.00000229669
27137			-0.00275066778 [math]\pm[/math] 0.00000184982
27136			-0.00239423237 [math]\pm[/math] 0.00000185134
27134			-0.00355581434 [math]\pm[/math] 0.00000168285
27133			-0.00252193724 [math]\pm[/math] 0.00000190408
27132			0.00096332202 [math]\pm[/math] 0.00000197909
27143			-0.00210486278 [math]\pm[/math] 0.00000322339
27141			-0.00301990556 [math]\pm[/math] 0.00000253085
27160			0.00171264744
27161			0.00224287304
27162			0.00118844445
27166			0.00077237006
27167			0.00216041281
27168			0.00083650625
27170			0.00151247511
27175			-0.01217485668
27176			-0.01049635167
27177			-0.01147445288
27179			-0.01025340153
27180			-0.00868272418
27181			-0.00973324188
27182			-0.00983862460
27183			-0.01901615252
27186			0.01079090635
27187			0.01155519076
27188			0.01086898605
27190			0.01181266490
27192			-0.00988459637
27193			-0.01047643036
27194			-0.01185520003

NPHE

To find out pion contamination in the electron sample i used Osipenko geometrical cuts. The number of photoelectrons before and after osipenko cuts are shown below:

No cuts	OSI Cuts
The number of photoelectrons without cuts	The number of photoelectrons with OSI cuts

For different fits:

The number of photoelectrons after OSICuts with two Gaussian fits

The number of photoelectrons after OSICuts with Landau+Gaussian fits

06/11/09

Pion Contamination

No cuts	OSI Cuts (Gauss(0)+Landau(3)+Gauss(6))	OSI Cuts (Gauss(0)+Gauss(3))	OSICuts + NPHE>2.5 (Gauss)
The number of photoelectrons without cuts	The number of photoelectrons with OSI cuts(gauss+landau+gauss)	The number of photoelectrons with OSI cuts two gaussian fits	The number of photoelectrons with OSI+NPHE cuts

OSICuts (Gauss(0)+Landau(3)+Gauss(6))

Assuming that the two gaussians represent number of photoelectrons and landau number of photons produced by high energy pions, the ratio of number of pions over the sum of electrons and pion in the electron candidate sample can be calculated in the following way:

OSIcut

[math] Pion Contamination = [/math]
[math] = \frac {Integral(landau(3))}{Integral(gauss(0) + landau(3) + gauss(6))} =[/math]
[math] = \frac{1.643 \times 10^9}{ 7.682 \times 10^9 + 1.643 \times 10^9 + 7.732 \times 10^9} = [/math]
[math] = 9.6324 % [/math]

OSICut+NPHE>2.5

[math] Pion Contamination = [/math]
[math] = \frac {Integral(landau(3))}{Integral(gauss(0) + landau(3) + gauss(6))} =[/math]
[math] = \frac{5.905 \times 10^8}{ 6.656 \times 10^9 + 5.905 \times 10^8 + 7.395 \times 10^9} = [/math]
[math] = 4.03305% [/math]

OSICuts (Gauss(0)+Gauss(3))

In case of only two gaussians, the number of photoelectrons produced by pions is described by Gauss(0) and the number of photoelectrons created by electrons is Gauss(3). Pion contamination is calculated below for both cases, without and with NPHE>2.5 cut.

OSICut

[math] Pion Contamination = [/math]
[math] = \frac {Integral(gauss(0))}{Integral(gauss(0) + gauss(3))} =[/math]
[math] = \frac{2.151 \times 10^8}{ 2.151 \times 10^8 + 1.594 \times 10^{10} } [/math]
[math] = 1.3 % [/math]

With NPHE>2.5 Cut

[math] Pion Contamination = 0 [/math]

Number of Events after NPHE>2.5 Cut

[math] Number of Events after NPHE\gt 2.5 Cut [/math] =
[math] = \frac{2.978 \times 10^8}{3.496 \times 10^8} = [/math]
[math] = 85.18 % [/math]

Counts in FCup

[math]Ratio of Counts 24/13 = \frac{2.131 \times 10^6}{2.116 \times 10^6} = 1.007 [/math]

6/12/09

1.) Improve Chi^2 in NPe fits.

2.) Calculate uncertainty in pion contamination measurement by changing mean and widths according to fit error.

3.) Pulse pair FC asymmetry, and End of Run accumulated FC asym.

pulse pair [math]\equiv \sum_i(\frac{FC(i)^+ - FC(i)^-}{FC(i)^+ + FC(i)^-})[/math]

End of Run sum [math]\equiv \frac {\sum_i(FC(i)^+) - \sum(FC(i)^-)}{\sum (FC(i)^+) + \sum(FC(i)^-)})[/math]

4.) Determine semi-inclusive statistic as function of X

Uncertainty in Pion Contamination

Maximum

[math] Pion Contamination = [/math]
[math] = \frac {Integral(landau(3))}{Integral(gauss(0) + landau(3) + gauss(6))} =[/math]
[math] = \frac{1.645 \times 10^9}{ 7.695 \times 10^9 + 1.645 \times 10^9 + 7.745 \times 10^9} = [/math]
[math] = 9.6283 % [/math]

[math] Pion Contamination = [/math]
[math] = \frac {Integral(landau(3))}{Integral(gauss(0) + landau(3) + gauss(6))} =[/math]
[math] = \frac{5.914 \times 10^8}{ 6.666 \times 10^9 + 5.914 \times 10^8 + 7.427 \times 10^9} = [/math]
[math] = 4.02740 % [/math]

Minimum

[math] Pion Contamination = [/math]
[math] = \frac {Integral(landau(3))}{Integral(gauss(0) + landau(3) + gauss(6))} =[/math]
[math] = \frac{1.642 \times 10^9}{ 7.67 \times 10^9 + 1.642 \times 10^9 + 7.719 \times 10^9} = [/math]
[math] = 9.64124 % [/math]

[math] Pion Contamination = [/math]
[math] = \frac {Integral(landau(3))}{Integral(gauss(0) + landau(3) + gauss(6))} =[/math]
[math] = \frac{5.895 \times 10^8}{ 6.645 \times 10^9 + 5.895 \times 10^8 + 7.401 \times 10^9} = [/math]
[math] = 4.02788 % [/math]

Delta_D_over_D