Annotation of ttbar/p20_taujets_note/Appendix.tex, revision 1.2
1.1 uid12904 1: \appendix
2:
3: \section{\label{app:trig_eff}Trigger Efficiencies}
4: %\begin{subappendices}
5:
6: \noindent In this appendix we present the trigger weight distributions of all MC samples
7: for different numbers of b-tagged jets. These are the weight distributions we referred to
8: in Sections \ref{sub:datasample} and \ref{sec:trig_param}.
9:
10:
11: \subsection{\label{app:taujets_trig_eff}Trigger Efficiencies for $\tau + jets$}
12: \begin{figure}[h]
13: \includegraphics[scale=0.28]{trigger_eff/taujets0eff}
14: \includegraphics[scale=0.28]{trigger_eff/taujets1eff}
15: \includegraphics[scale=0.28]{trigger_eff/taujets2eff}
16: \includegraphics[scale=0.28]{trigger_eff/taujets3eff}
17: \caption{Trigger Efficiencies for $\tau + jets$.}
18:
19: %\label{fig:variables_type2_bveto}
20: \end{figure}
21:
22:
23: \subsection{\label{app:taujets_trig_eff}Trigger Efficiencies for $e + jets$}
24: \begin{figure}[h]
25: \includegraphics[scale=0.28]{trigger_eff/ejets0eff}
26: \includegraphics[scale=0.28]{trigger_eff/ejets1eff}
27: \includegraphics[scale=0.28]{trigger_eff/ejets2eff}
28: \includegraphics[scale=0.28]{trigger_eff/ejets3eff}
29: \caption{Trigger Efficiencies for $e + jets$.}
30:
31: %\label{fig:variables_type2_bveto}
32: \end{figure}
33:
34: \clearpage
35:
36: \subsection{\label{app:mujets_trig_eff}Trigger Efficiencies for $\mu + jets$}
37: \begin{figure}[h]
38: \includegraphics[scale=0.28]{trigger_eff/mujets0eff}
39: \includegraphics[scale=0.28]{trigger_eff/mujets1eff}
40: \includegraphics[scale=0.28]{trigger_eff/mujets2eff}
41: \includegraphics[scale=0.28]{trigger_eff/mujets3eff}
42: \caption{Trigger Efficiencies for $\mu + jets$.}
43:
44: %\label{fig:variables_type2_bveto}
45: \end{figure}
46:
47:
48: \subsection{\label{app:dilep_trig_eff}Trigger Efficiencies for $dilepton$}
49: \begin{figure}[h]
50: \includegraphics[scale=0.28]{trigger_eff/dilep0eff}
51: \includegraphics[scale=0.28]{trigger_eff/dilep1eff}
52: \includegraphics[scale=0.28]{trigger_eff/dilep2eff}
53: \includegraphics[scale=0.28]{trigger_eff/dilep3eff}
54: \caption{Trigger Efficiencies for $dilepton$.}
55:
56: %\label{fig:variables_type2_bveto}
57: \end{figure}
58:
59:
60: \clearpage
61:
62:
1.2 ! uid12904 63: %\subsection{\label{app:alljets_trig_eff}Trigger Efficiencies for $alljets$}
! 64: %\begin{figure}[h]
! 65: %\includegraphics[scale=0.28]{trigger_eff/alljets0eff}
! 66: %\includegraphics[scale=0.28]{trigger_eff/alljets1eff}
! 67: %\includegraphics[scale=0.28]{trigger_eff/alljets2eff}
! 68: %\includegraphics[scale=0.28]{trigger_eff/alljets3eff}
! 69: %\caption{Trigger Efficiencies for $alljets$.}
1.1 uid12904 70:
71: %\label{fig:variables_type2_bveto}
1.2 ! uid12904 72: %\end{figure}
1.1 uid12904 73:
74:
75: \subsection{\label{app:Wjjjets_trig_eff}Trigger Efficiencies for $Wjj + jets$}
76: \begin{figure}[h]
77: \includegraphics[scale=0.28]{trigger_eff/Wjjjets0eff}
78: \includegraphics[scale=0.28]{trigger_eff/Wjjjets1eff}
79: \includegraphics[scale=0.28]{trigger_eff/Wjjjets2eff}
80: \includegraphics[scale=0.28]{trigger_eff/Wjjjets3eff}
81: \caption{Trigger Efficiencies for $Wjj + jets$.}
82:
83: %\label{fig:variables_type2_bveto}
84: \end{figure}
85:
1.2 ! uid12904 86: %\clearpage
1.1 uid12904 87:
88: \subsection{\label{app:Wbbjets_trig_eff}Trigger Efficiencies for $Wbb + jets$}
89: \begin{figure}[h]
90: \includegraphics[scale=0.28]{trigger_eff/Wbbjets0eff}
91: \includegraphics[scale=0.28]{trigger_eff/Wbbjets1eff}
92: \includegraphics[scale=0.28]{trigger_eff/Wbbjets2eff}
93: \includegraphics[scale=0.28]{trigger_eff/Wbbjets3eff}
94: \caption{Trigger Efficiencies for $Wbb + jets$.}
95:
96: %\label{fig:variables_type2_bveto}
97: \end{figure}
98:
1.2 ! uid12904 99: \clearpage
1.1 uid12904 100:
101: \subsection{\label{app:Wccjets_trig_eff}Trigger Efficiencies for $Wcc + jets$}
102: \begin{figure}[h]
103: \includegraphics[scale=0.28]{trigger_eff/Wccjets0eff}
104: \includegraphics[scale=0.28]{trigger_eff/Wccjets1eff}
105: \includegraphics[scale=0.28]{trigger_eff/Wccjets2eff}
106: \includegraphics[scale=0.28]{trigger_eff/Wccjets3eff}
107: \caption{Trigger Efficiencies for $Wcc + jets$.}
108:
109: %\label{fig:variables_type2_bveto}
110: \end{figure}
111:
112:
1.2 ! uid12904 113: %\clearpage
1.1 uid12904 114:
115:
116: \subsection{\label{app:Zlpeejets_trig_eff}Trigger Efficiencies for $Zjj + jets \rightarrow ee + jj + jets$}
117: \begin{figure}[h]
118: \includegraphics[scale=0.28]{trigger_eff/Zlpee0eff}
119: \includegraphics[scale=0.28]{trigger_eff/Zlpee1eff}
120: \includegraphics[scale=0.28]{trigger_eff/Zlpee2eff}
121: \includegraphics[scale=0.28]{trigger_eff/Zlpee3eff}
122: \caption{Trigger Efficiencies for $Zjj + jets \rightarrow ee + jj + jets$.}
123:
124: %\label{fig:variables_type2_bveto}
125: \end{figure}
126:
127:
1.2 ! uid12904 128: \clearpage
1.1 uid12904 129:
130: \subsection{\label{app:Zbbeejets_trig_eff}Trigger Efficiencies for $Zbb + jets \rightarrow ee + bb + jets$}
131: \begin{figure}[h]
132: \includegraphics[scale=0.28]{trigger_eff/Zbbee0eff}
133: \includegraphics[scale=0.28]{trigger_eff/Zbbee1eff}
134: \includegraphics[scale=0.28]{trigger_eff/Zbbee2eff}
135: \includegraphics[scale=0.28]{trigger_eff/Zbbee3eff}
136: \caption{Trigger Efficiencies for $Zbb + jets \rightarrow ee + bb + jets$.}
137:
138: %\label{fig:variables_type2_bveto}
139: \end{figure}
140:
1.2 ! uid12904 141: %\clearpage
1.1 uid12904 142:
143: \subsection{\label{app:Zcceejets_trig_eff}Trigger Efficiencies for $Zcc + jets \rightarrow ee + cc + jets$}
144: \begin{figure}[h]
145: \includegraphics[scale=0.28]{trigger_eff/Zccee0eff}
146: \includegraphics[scale=0.28]{trigger_eff/Zccee1eff}
147: \includegraphics[scale=0.28]{trigger_eff/Zccee2eff}
148: \includegraphics[scale=0.28]{trigger_eff/Zccee3eff}
149: \caption{Trigger Efficiencies for $Zcc + jets \rightarrow ee + cc + jets$.}
150:
151: %\label{fig:variables_type2_bveto}
152: \end{figure}
153:
1.2 ! uid12904 154: \clearpage
1.1 uid12904 155:
156: \subsection{\label{app:Zlpmumujets_trig_eff}Trigger Efficiencies for $Zjj + jets \rightarrow \mu\mu + jj + jets$}
157: \begin{figure}[h]
158: \includegraphics[scale=0.28]{trigger_eff/Zlpmumu0eff}
159: \includegraphics[scale=0.28]{trigger_eff/Zlpmumu1eff}
160: \includegraphics[scale=0.28]{trigger_eff/Zlpmumu2eff}
161: \includegraphics[scale=0.28]{trigger_eff/Zlpmumu3eff}
162: \caption{Trigger Efficiencies for $Zjj + jets \rightarrow \mu\mu + jj + jets$.}
163:
164: %\label{fig:variables_type2_bveto}
165: \end{figure}
166:
167:
1.2 ! uid12904 168: %\clearpage
1.1 uid12904 169:
170:
171:
172: \subsection{\label{app:Zbbmumujets_trig_eff}Trigger Efficiencies for $Zbb + jets \rightarrow \mu\mu + bb + jets$}
173: \begin{figure}[h]
174: \includegraphics[scale=0.28]{trigger_eff/Zbbmumu0eff}
175: \includegraphics[scale=0.28]{trigger_eff/Zbbmumu1eff}
176: \includegraphics[scale=0.28]{trigger_eff/Zbbmumu2eff}
177: \includegraphics[scale=0.28]{trigger_eff/Zbbmumu3eff}
178: \caption{Trigger Efficiencies for $Zbb + jets \rightarrow \mu\mu + bb + jets$.}
179:
180: %\label{fig:variables_type2_bveto}
181: \end{figure}
182:
1.2 ! uid12904 183: \clearpage
1.1 uid12904 184:
185: \subsection{\label{app:Zccmumujets_trig_eff}Trigger Efficiencies for $Zcc + jets \rightarrow \mu\mu + cc + jets$}
186: \begin{figure}[h]
187: \includegraphics[scale=0.28]{trigger_eff/Zccmumu0eff}
188: \includegraphics[scale=0.28]{trigger_eff/Zccmumu1eff}
189: \includegraphics[scale=0.28]{trigger_eff/Zccmumu2eff}
190: \includegraphics[scale=0.28]{trigger_eff/Zccmumu3eff}
191: \caption{Trigger Efficiencies for $Zcc + jets \rightarrow \mu\mu + cc + jets$.}
192:
193: %\label{fig:variables_type2_bveto}
194: \end{figure}
195:
1.2 ! uid12904 196: %\clearpage
1.1 uid12904 197:
198:
199: \subsection{\label{app:Zlptautaujets_trig_eff}Trigger Efficiencies for $Zjj + jets \rightarrow \tau\tau + jj + jets$}
200: \begin{figure}[h]
201: \includegraphics[scale=0.28]{trigger_eff/Zlptautau0eff}
202: \includegraphics[scale=0.28]{trigger_eff/Zlptautau1eff}
203: \includegraphics[scale=0.28]{trigger_eff/Zlptautau2eff}
204: \includegraphics[scale=0.28]{trigger_eff/Zlptautau3eff}
205: \caption{Trigger Efficiencies for $Zjj + jets \rightarrow \tau\tau + jj + jets$.}
206:
207: %\label{fig:variables_type2_bveto}
208: \end{figure}
209:
210:
1.2 ! uid12904 211: \clearpage
1.1 uid12904 212:
213: \subsection{\label{app:Zbbtautaujets_trig_eff}Trigger Efficiencies for $Zbb + jets \rightarrow \tau\tau + bb + jets$}
214: \begin{figure}[h]
215: \includegraphics[scale=0.28]{trigger_eff/Zbbtautau0eff}
216: \includegraphics[scale=0.28]{trigger_eff/Zbbtautau1eff}
217: \includegraphics[scale=0.28]{trigger_eff/Zbbtautau2eff}
218: \includegraphics[scale=0.28]{trigger_eff/Zbbtautau3eff}
219: \caption{Trigger Efficiencies for $Zbb + jets \rightarrow \tau\tau + bb + jets$.}
220:
221: %\label{fig:variables_type2_bveto}
222: \end{figure}
223:
224:
225:
226:
227: \subsection{\label{app:Zcctautaujets_trig_eff}Trigger Efficiencies for $Zcc + jets \rightarrow \tau\tau + cc + jets$}
228: \begin{figure}[h]
229: \includegraphics[scale=0.28]{trigger_eff/Zcctautau0eff}
230: \includegraphics[scale=0.28]{trigger_eff/Zcctautau1eff}
231: \includegraphics[scale=0.28]{trigger_eff/Zcctautau2eff}
232: \includegraphics[scale=0.28]{trigger_eff/Zcctautau3eff}
233: \caption{Trigger Efficiencies for $Zcc + jets \rightarrow \tau\tau + cc + jets$.}
234:
235: %\label{fig:variables_type2_bveto}
236: \end{figure}
237:
238:
1.2 ! uid12904 239: \clearpage
! 240:
! 241:
1.1 uid12904 242: \subsection{\label{app:Zlpnunuets_trig_eff}Trigger Efficiencies for $Zjj + jets \rightarrow \nu\nu + jj + jets$}
243: \begin{figure}[h]
244: \includegraphics[scale=0.28]{trigger_eff/Zlpnunu0eff}
245: \includegraphics[scale=0.28]{trigger_eff/Zlpnunu1eff}
246: \includegraphics[scale=0.28]{trigger_eff/Zlpnunu2eff}
247: \includegraphics[scale=0.28]{trigger_eff/Zlpnunu3eff}
248: \caption{Trigger Efficiencies for $Zjj + jets \rightarrow \nu\nu + jj + jets$.}
249:
250: %\label{fig:variables_type2_bveto}
251: \end{figure}
252:
253:
254:
255:
256: \subsection{\label{app:Zbbnunujets_trig_eff}Trigger Efficiencies for $Zbb + jets \rightarrow \nu\nu + bb + jets$}
257: \begin{figure}[h]
258: \includegraphics[scale=0.28]{trigger_eff/Zbbnunu0eff}
259: \includegraphics[scale=0.28]{trigger_eff/Zbbnunu1eff}
260: \includegraphics[scale=0.28]{trigger_eff/Zbbnunu2eff}
261: \includegraphics[scale=0.28]{trigger_eff/Zbbnunu3eff}
262: \caption{Trigger Efficiencies for $Zbb + jets \rightarrow \nu\nu + bb + jets$.}
263:
264: %\label{fig:variables_type2_bveto}
265: \end{figure}
266:
267:
1.2 ! uid12904 268: \clearpage
! 269:
! 270:
1.1 uid12904 271: \subsection{\label{app:Zccnunujets_trig_eff}Trigger Efficiencies for $Zcc + jets \rightarrow \nu\nu + cc + jets$}
272: \begin{figure}[h]
273: \includegraphics[scale=0.28]{trigger_eff/Zccnunu0eff}
274: \includegraphics[scale=0.28]{trigger_eff/Zccnunu1eff}
275: \includegraphics[scale=0.28]{trigger_eff/Zccnunu2eff}
276: \includegraphics[scale=0.28]{trigger_eff/Zccnunu3eff}
277: \caption{Trigger Efficiencies for $Zcc + jets \rightarrow \nu\nu + cc + jets$.}
278:
279: %\label{fig:variables_type2_bveto}
280: \end{figure}
281:
282:
1.2 ! uid12904 283: \clearpage
! 284: %\newpage
1.1 uid12904 285:
286:
1.2 ! uid12904 287: \section{\label{app:turnon} Turn-on curves for trigger JT2$\_$3JT15L$\_$IP$\_$VX}
1.1 uid12904 288:
1.2 ! uid12904 289: \noindent Here are shown all turn-on curves for all three levels of the trigger JT2$\_$3JT15L$\_$IP$\_$VX
1.1 uid12904 290: as described in Section \ref{sec:trig_param}.
291:
292:
1.2 ! uid12904 293: \subsection{\label{app:jetturnon_L1} Level 1 jet turn-on curves for trigger JT2$\_$3JT15L$\_$IP$\_$VX}
1.1 uid12904 294:
295: \begin{figure}[h]
296: \centering
297: \subfigure[$p_{T} >$ 8~GeV]{\epsfig{file=lowLum/l1jetspt8.eps,width=4.7cm}}
298: \subfigure[$p_{T} >$ 15~GeV]{\epsfig{file=lowLum/l1jetspt15.eps,width=4.7cm}}
299: \subfigure[$p_{T} >$ 30~GeV]{\epsfig{file=lowLum/l1jetspt30.eps,width=4.7cm}}
300: \caption{Level 1 jet turn-on curves, low luminosity.}
301: \label{fig:l1jetslo}
302: \end{figure}
303:
1.2 ! uid12904 304: %\newpage
1.1 uid12904 305:
306: \begin{figure}[h]
307: \centering
308: \subfigure[$p_{T} >$ 8~GeV]{\epsfig{file=medLum/l1jetspt8.eps,width=4.7cm}}
309: \subfigure[$p_{T} >$ 15~GeV]{\epsfig{file=medLum/l1jetspt15.eps,width=4.7cm}}
310: \subfigure[$p_{T} >$ 30~GeV]{\epsfig{file=medLum/l1jetspt30.eps,width=4.7cm}}
311: \caption{Level 1 jet turn-on curves, medium luminosity.}
312: \label{fig:l1jets}
313: \end{figure}
314:
315:
316: \begin{figure}[h]
317: \centering
318: \subfigure[$p_{T} >$ 8~GeV]{\epsfig{file=highLum/l1jetspt8.eps,width=4.7cm}}
319: \subfigure[$p_{T} >$ 15~GeV]{\epsfig{file=highLum/l1jetspt15.eps,width=4.7cm}}
320: \subfigure[$p_{T} >$ 30~GeV]{\epsfig{file=highLum/l1jetspt30.eps,width=4.7cm}}
321: \caption{Level 1 jet turn-on curves, high luminosity.}
322: \label{fig:l1jetshi}
323: \end{figure}
324:
325: \newpage
326:
327:
1.2 ! uid12904 328: \subsection{\label{app:jetturnon_L2} Level 2 jet turn-on curves for trigger JT2$\_$3JT15L$\_$IP$\_$VX}
1.1 uid12904 329:
330: \begin{figure}[h]
331: \centering
332: \subfigure[Low luminosity $p_{T} >$ 8~GeV]{\epsfig{file=lowLum/l2jetspt8.eps,width=4.7cm}}
333: \subfigure[Medium luminosity $p_{T} >$ 8~GeV]{\epsfig{file=medLum/l2jetspt8.eps,width=4.7cm}}
334: \subfigure[high luminosity $p_{T} >$ 8~GeV]{\epsfig{file=highLum/l2jetspt8.eps,width=4.7cm}}
335: \caption{Level 2 $p_{T} >$ 8~GeV jets turn-on curves.}
336: \label{fig:l2jetsalllumi}
337: \end{figure}
338:
339:
1.2 ! uid12904 340: \subsection{\label{app:htturnon_L2} Level 2 $H_{T}$ turn-on curves for trigger JT2$\_$3JT15L$\_$IP$\_$VX}
1.1 uid12904 341:
342: \begin{figure}[h]
343: \centering
344: \subfigure[$H_{T} >$ 75~GeV]{\epsfig{file=lowLum/l2ht75.eps,width=4.7cm}}
345: \subfigure[$H_{T} >$ 100~GeV]{\epsfig{file=lowLum/l2ht100.eps,width=4.7cm}}
346: \caption{L2 $H_{T}$ turn-on curves, low luminosity.}
347: \label{fig:l2htlo}
348: \end{figure}
349:
350: \begin{figure}[h]
351: \centering
352: \subfigure[$H_{T} >$ 75~GeV]{\epsfig{file=medLum/l2ht75.eps,width=4.7cm}}
353: \subfigure[$H_{T} >$ 100~GeV]{\epsfig{file=medLum/l2ht100.eps,width=4.7cm}}
354: \caption{L2 $H_{T}$ turn-on curves, medium luminosity.}
355: \label{fig:l2ht}
356: \end{figure}
357:
358: \begin{figure}[h]
359: \centering
360: \subfigure[$H_{T} >$ 75~GeV]{\epsfig{file=highLum/l2ht75.eps,width=4.7cm}}
361: \subfigure[$H_{T} >$ 100~GeV]{\epsfig{file=highLum/l2ht100.eps,width=4.7cm}}
362: \caption{L2 $H_{T}$ turn-on curves, high luminosity.}
363: \label{fig:l2hthi}
364: \end{figure}
365:
366: \newpage
367:
368:
1.2 ! uid12904 369: \subsection{\label{app:mhtturnon_L2} Level 2 $\not\!\!E_{T}$ turn-on curves for trigger JT2$\_$3JT15L$\_$IP$\_$VX}
1.1 uid12904 370:
371: \begin{figure}[h]
372: \centering
373: \subfigure[$\not\!\!E_{T}$ $>$ 10~GeV]{\epsfig{file=lowLum/l2mhtv15.eps,width=4.7cm}}
374: \subfigure[$\not\!\!E_{T}$ $>$ 20~GeV]{\epsfig{file=lowLum/l2mhtv16.eps,width=4.7cm}}
375: \caption{L2 $\not\!\!E_{T}$ turn-on curves, low luminosity.}
376: \label{fig:l2mhtlo}
377: \end{figure}
378:
379:
380: \begin{figure}[h]
381: \centering
382: \subfigure[$\not\!\!E_{T}$ $>$ 10~GeV]{\epsfig{file=medLum/l2mhtv15.eps,width=4.7cm}}
383: \subfigure[$\not\!\!E_{T}$ $>$ 20~GeV]{\epsfig{file=medLum/l2mhtv16.eps,width=4.7cm}}
384: \caption{L2 $\not\!\!E_{T}$ turn-on curves, medium luminosity.}
385: \label{fig:l2mht}
386: \end{figure}
387:
388: \begin{figure}[h]
389: \centering
390: \subfigure[$\not\!\!E_{T}$ $>$ 10~GeV]{\epsfig{file=highLum/l2mhtv15.eps,width=4.7cm}}
391: \subfigure[$\not\!\!E_{T}$ $>$ 20~GeV]{\epsfig{file=highLum/l2mhtv16.eps,width=4.7cm}}
392: \caption{L2 $\not\!\!E_{T}$ turn-on curves, high luminosity.}
393: \label{fig:l2mhthi}
394: \end{figure}
395:
396:
397: \newpage
398:
399:
1.2 ! uid12904 400: \subsection{\label{app:spherturnon_L2} Level 2 Sphericity turn-on curves for trigger JT2$\_$3JT15L$\_$IP$\_$VX}
1.1 uid12904 401:
402: \begin{figure}[h]
403: \centering
404: \subfigure[Sphericity $>$ 0.1 turn-on curve, low luminosity]{\epsfig{file=lowLum/l2spher.eps,width=4.7cm}}
405: \subfigure[Sphericity $>$ 0.1 turn-on curve, medium luminosity]{\epsfig{file=lowLum/l2spher.eps,width=4.7cm}}
406: \subfigure[Sphericity $>$ 0.1 turn-on curve, high luminosity]{\epsfig{file=medLum/l2spher.eps,width=4.7cm}}
407: \caption{L2 Sphericity turn-on curves.}
408: \label{fig:l2spher}
409: \end{figure}
410:
411:
1.2 ! uid12904 412: \subsection{\label{app:sttip_L2} Level 2 STTIP turn-on curves for trigger JT2$\_$3JT15L$\_$IP$\_$VX}
1.1 uid12904 413:
414: \begin{figure}[h]
415: \centering
416: \subfigure[L2STTIP, 0 and 1 tight NN tags]{\epsfig{file=lowLum/l2stt01taglol.eps,width=4.7cm}}
417: \subfigure[L2STTIP, 2 and 3 tight NN tags]{\epsfig{file=lowLum/l2stt23taglol.eps,width=4.7cm}}
418: \caption{L2STTIP efficiency in the low luminosity range. Left: events with 0 (red) and 1 (black) tight NN b-tags. Right: events with 2 (red) and 3 (black) tight NN b-tags.}
419: \label{fig:l2STTlo}
420: \end{figure}
421:
422: \begin{figure}[h]
423: \centering
424: \subfigure[L2STTIP, 0 and 1 tight NN tags]{\epsfig{file=medLum/l2stt01tag.eps,width=4.7cm}}
425: \subfigure[L2STTIP, 2 and 3 tight NN tags]{\epsfig{file=medLum/l2stt23tag.eps,width=4.7cm}}
426: \caption{L2STTIP efficiency in the medium luminosity range. Left: events with 0 (red) and 1 (black) tight NN b-tags. Right: events with 2 (red) and 3 (black) tight NN b-tags.}
427: \label{fig:l2STT}
428: \end{figure}
429:
430: \begin{figure}[h]
431: \centering
432: \subfigure[L2STTIP, 0 and 1 tight NN tags]{\epsfig{file=highLum/l2stt01taghil.eps,width=4.7cm}}
433: \subfigure[L2STTIP, 2 and 3 tight NN tags]{\epsfig{file=highLum/l2stt23taghil.eps,width=4.7cm}}
434: \caption{L2STTIP efficiency in the high luminosity range. Left: events with 0 (red) and 1 (black) tight NN b-tags. Right: events with 2 (red) and 3 (black) tight NN b-tags.}
435: \label{fig:l2STThi}
436: \end{figure}
437:
438: \newpage
439:
1.2 ! uid12904 440: \subsection{\label{app:jetturnon_L3} Level 3 jet turn-on curves for trigger JT2$\_$3JT15L$\_$IP$\_$VX}
1.1 uid12904 441:
442: \begin{figure}[h]
443: \centering
444: \subfigure[$p_{T} >$ 15~GeV]{\epsfig{file=lowLum/l3jetspt15.eps,width=4.7cm}}
445: \subfigure[$p_{T} >$ 25~GeV]{\epsfig{file=lowLum/l3jetspt25.eps,width=4.7cm}}
446: \caption{L3 jet turn-on curves, low luminosity.}
447: \label{fig:l3jetslo}
448: \end{figure}
449: %
450:
451: \newpage
452:
453:
454: \begin{figure}[h]
455: \centering
456: \subfigure[$p_{T} >$ 15~GeV]{\epsfig{file=medLum/l3jetspt15.eps,width=4.7cm}}
457: \subfigure[$p_{T} >$ 25~GeV]{\epsfig{file=medLum/l3jetspt25.eps,width=4.7cm}}
458: \caption{L3 jet turn-on curves, medium luminosity.}
459: \label{fig:l3jets}
460: \end{figure}
461: %
462: \begin{figure}[h]
463: \centering
464: \subfigure[$p_{T} >$ 15~GeV]{\epsfig{file=highLum/l3jetspt15.eps,width=4.7cm}}
465: \subfigure[$p_{T} >$ 25~GeV]{\epsfig{file=highLum/l3jetspt25.eps,width=4.7cm}}
466: \caption{L3 jet turn-on curves, high luminosity.}
467: \label{fig:l3jetshi}
468: \end{figure}
469:
470:
471: \subsection{\label{app:btagturnon_L3} Level 3 b-tag on curves for trigger JT2$\_$3JT15L$\_$IP$\_$VX}
472:
473: \begin{figure}[h]
474: %\vspace{-0.5cm}
475: \centering
476: \subfigure[0 and 1 $b$-tags.]{\epsfig{file=lowLum/l3btag01taglol.eps,width=4.0cm}}
477: \subfigure[2 and 3 $b$-tags.]{\epsfig{file=lowLum/l3btag23taglol.eps,width=4.0cm}}
478: %\vspace{-0.5cm}
479: \caption[L3 IP Trigger]{(a) Efficiency of the L3 $b$-tag (Level3 Event $b$-tag$<$ 0.4) for the low luminosity
480: range in triggerlist v15. The selected events passed the rest of the trigger and offline event selection and
481: had zero (red) or one (black) offline NN (TIGHT) $b$-tags. (b) Same for events with 2(red) and 3(black) offline NN (TIGHT) $b$-tags.}
482: \label{fig:l3iplo}
483: \end{figure}
484:
485: \newpage
486:
487: \begin{figure}[h]
488: %\vspace{-0.5cm}
489: \centering
490: \subfigure[0 and 1 $b$-tags.]{\epsfig{file=medLum/l3btag01tag.eps,width=4.0cm}}
491: \subfigure[2 and 3 $b$-tags.]{\epsfig{file=medLum/l3btag2tag.eps,width=4.0cm}}
492: %\vspace{-0.5cm}
493: \caption[L3 IP Trigger]{(a) Efficiency of the L3 $b$-tag (Level3 Event $b$-tag$<$ 0.4) for the medium luminosity
494: range in triggerlist v15. The selected events passed the rest of the trigger and offline event selection and had
495: zero (red) or one (black) offline NN (TIGHT) $b$-tags. (b) Same for events with 2(red) and 3(black) offline NN (TIGHT) $b$-tags.}
496: \label{fig:l3ip}
497: \end{figure}
498:
499: \begin{figure}[h]
500: %\vspace{-0.5cm}
501: \centering
502: \subfigure[0 and 1 $b$-tags.]{\epsfig{file=highLum/l3btag01taghil.eps,width=4.0cm}}
503: \subfigure[2 and 3 $b$-tags.]{\epsfig{file=highLum/l3btag23taghil.eps,width=4.0cm}}
504: %\vspace{-0.5cm}
505: \caption[L3 IP Trigger]{(a) Efficiency of the L3 $b$-tag (Level3 Event $b$-tag$<$ 0.4) for the high luminosity
506: range in triggerlist v15. The selected events passed the rest of the trigger and offline event selection and had
507: zero (red) or one (black) offline NN (TIGHT) $b$-tags. (b) Same for events with 2(red) and 3(black) offline NN (TIGHT) $b$-tags.}
508: \label{fig:l3iphi}
509: \end{figure}
510:
511:
512: \begin{figure}[h]
513: %\vspace{-0.5cm}
514: \centering
515: \subfigure[0 and 1 $b$-tags.]{\epsfig{file=lowLum/l3btag01tagv16lol.eps,height=4.0cm,width=4.0cm}}
516: \subfigure[2 and 3 $b$-tags.]{\epsfig{file=lowLum/l3btag2tagv16lol.eps,height=4.0cm,width=4.0cm}}
517: %\vspace{-0.5cm}
518: \caption[L3 IP Trigger]{(a) Efficiency of the L3 $b$-tag (Level3 Event $b$-tag$<$ 0.4) for the low luminosity
519: range in triggerlist v16. The selected events passed the rest of the trigger and offline event selection and
520: had zero (red) or one (black) offline NN (TIGHT) $b$-tags. (b) Same for events with 2(red) and 3(black) offline NN (TIGHT) $b$-tags.}
521: \label{fig:l3ipv16lo}
522: \end{figure}
523:
524: \begin{figure}[h]
525: %\vspace{-0.5cm}
526: \centering
527: \subfigure[0 and 1 $b$-tags.]{\epsfig{file=medLum/l3btag01tagv16.eps,height=4.0cm,width=4.0cm}}
528: \subfigure[2 and 3 $b$-tags.]{\epsfig{file=medLum/l3btag2tagv16.eps,height=4.0cm,width=4.0cm}}
529: %\vspace{-0.5cm}
530: \caption[L3 IP Trigger]{(a) Efficiency of the L3 $b$-tag (Level3 Event $b$-tag$<$ 0.4) for the medium luminosity
531: range in triggerlist v16. The selected events passed the rest of the trigger and offline event selection and had
532: zero (red) or one (black) offline NN (TIGHT) $b$-tags. (b) Same for events with 2(red) and 3(black) offline NN (TIGHT) $b$-tags.}
533: \label{fig:l3ipv16}
534: \end{figure}
535:
536: \begin{figure}[h]
537: %\vspace{-0.5cm}
538: \centering
539: \subfigure[0 and 1 $b$-tags.]{\epsfig{file=highLum/l3btag01tagv16hil.eps,height=4.0cm,width=4.0cm}}
540: \subfigure[2 and 3 $b$-tags.]{\epsfig{file=highLum/l3btag2tagv16hil.eps,height=4.0cm,width=4.0cm}}
541: %\vspace{-0.5cm}
542: \caption[L3 IP Trigger]{(a) Efficiency of the L3 $b$-tag (Level3 Event $b$-tag$<$ 0.4) for the high luminosity
543: range in triggerlist v16. The selected events passed the rest of the trigger and offline event selection and had
544: zero (red) or one (black) offline NN (TIGHT) $b$-tags. (b) Same for events with 2(red) and 3(black) offline NN (TIGHT) $b$-tags.}
545: \label{fig:l3ipv16hi}
546: \end{figure}
547:
548: \clearpage
549:
550:
551: \section{\label{app:discri_var}Discriminant variables}
552:
553: \noindent This appendix shows normalized plots of signal and background samples
1.2 ! uid12904 554: for all discriminant variables tested AND/OR used in this analysis.
1.1 uid12904 555:
556: \begin{figure}[h]
557: \includegraphics[scale=0.30]{plots/metl_allEW.eps}
558: \includegraphics[scale=0.30]{variables/aplan_all}
559: \includegraphics[scale=0.30]{variables/cent_all}
560: \includegraphics[scale=0.30]{variables/sqrts_all}
561: \includegraphics[scale=0.30]{variables/spher_all}
562: \includegraphics[scale=0.30]{variables/ht_all.eps}
563: \includegraphics[scale=0.30]{variables/topmassl_all}
564: \includegraphics[scale=0.30]{variables/costhetastar_all}
565:
566: \caption{Discriminant variables.}
567:
568: %\label{fig:variables_type2_bveto}
569: \end{figure}
570:
571: \clearpage
572:
573:
574: \section{\label{app:set_opt}Set optimization}
575:
1.2 ! uid12904 576: \noindent This appendix shows plots of the figure of merit (Eq. \ref{merit}) used to
1.1 uid12904 577: perform the NN variables set optimization as described in Section \ref{sub:NN-optimization}.
578:
579: \begin{figure}[b]
580: \includegraphics[scale=0.27]{SetOpt/ensemble1-40}
581: \includegraphics[scale=0.27]{SetOpt/ensemble12-40}
582: \includegraphics[scale=0.27]{SetOpt/ensemble13-40}
583: \includegraphics[scale=0.27]{SetOpt/ensemble14-40}
584: \includegraphics[scale=0.27]{SetOpt/ensemble15-40}
585: \includegraphics[scale=0.27]{SetOpt/ensemble3-40}
586: \includegraphics[scale=0.27]{SetOpt/ensemble4-40}
587: \includegraphics[scale=0.27]{SetOpt/ensemble5-40}
588: \includegraphics[scale=0.27]{SetOpt/ensemble7-40}
589: \includegraphics[scale=0.27]{SetOpt/ensemble9-40}
590: \includegraphics[scale=0.27]{SetOpt/ensemble10-40}
591: \includegraphics[scale=0.27]{SetOpt/ensemble12A-40}
592: \includegraphics[scale=0.27]{SetOpt/ensemble13A-40}
593: \includegraphics[scale=0.27]{SetOpt/ensemble14A-40}
594: \includegraphics[scale=0.27]{SetOpt/ensemble15A-40}
595: \caption{Sets of NN inputs variables with $\not\!\! E_{T}$ significance $>$ 4.0 for set optimization.}
596: \end{figure}
597:
598: \clearpage
599:
600: \begin{figure}[b]
1.2 ! uid12904 601: \includegraphics[scale=0.27]{SetOpt/ensemble16A-40}
! 602: \includegraphics[scale=0.27]{SetOpt/ensemble17A-40}
! 603: \includegraphics[scale=0.27]{SetOpt/ensemble18A-40}
1.1 uid12904 604: \includegraphics[scale=0.27]{SetOpt/ensemble19A-40}
605: \includegraphics[scale=0.27]{SetOpt/ensemble20-40}
606: \includegraphics[scale=0.27]{SetOpt/ensemble21-40}
607: \includegraphics[scale=0.27]{SetOpt/ensemble22-40}
608: \includegraphics[scale=0.27]{SetOpt/ensemble23-40}
609: \includegraphics[scale=0.27]{SetOpt/ensemble24-40}
610: \includegraphics[scale=0.27]{SetOpt/ensemble25-40}
611: \includegraphics[scale=0.27]{SetOpt/ensemble26-40}
612: \includegraphics[scale=0.27]{SetOpt/ensemble27-40}
613: \includegraphics[scale=0.27]{SetOpt/ensemble28-40}
614: \includegraphics[scale=0.27]{SetOpt/ensemble29-40}
615: \includegraphics[scale=0.27]{SetOpt/ensemble30-40}
616: \includegraphics[scale=0.27]{SetOpt/ensemble31-40}
617: \includegraphics[scale=0.27]{SetOpt/ensembleMS-40}
618: \includegraphics[scale=0.27]{SetOpt/ensemble33-40}
619: \caption{Sets of NN inputs variables with $\not\!\! E_{T}$ significance $>$ 4.0 for set optimization.}
1.2 ! uid12904 620: \end{figure}
1.1 uid12904 621:
622:
623: \clearpage
624:
625: \section{\label{app:metl_opt}$\not\!\! E_{T}$ significance optimization}
626:
627: \begin{figure}[h]
628: \includegraphics[scale=0.27]{SetOpt/ensembleMS-30}
629: \includegraphics[scale=0.27]{SetOpt/ensembleMS-35}
630: \includegraphics[scale=0.27]{SetOpt/ensembleMS-40}
631: \includegraphics[scale=0.27]{SetOpt/ensembleMS-45}
632: \includegraphics[scale=0.27]{SetOpt/ensembleMS50}
633: %\includegraphics[scale=0.27]{SetOpt/pull9-35}
634: %\includegraphics[scale=0.27]{SetOpt/pull9-40}
635: %\includegraphics[scale=0.27]{SetOpt/pull9-45}
636: %\includegraphics[scale=0.27]{SetOpt/pull9-50}
637: %\includegraphics[scale=0.27]{SetOpt/pull9-55}
638:
1.2 ! uid12904 639: \caption{Variation of $\not\!\! E_{T}$ significance cut for Set 32 = METsig, {$H_{T}$}, topmassl, aplan, Mjjtau.}
! 640:
! 641: %\label{fig:variables_type2_bveto}
! 642: \end{figure}
! 643:
! 644: \clearpage
! 645:
! 646:
! 647: \section{\label{app:Topo}Topological variables}
! 648:
! 649: In this section we show distributions of the topological variables used in this analysis in order to
! 650: check the agreement between data and Monte Carlo in all cases. Plots are separated into two sets:
! 651: signal sample and b-veto control plots.
! 652:
! 653: \subsection{\label{sub:signalplots}Signal sample plots}
! 654:
! 655: As stated in Section \ref{sub:Results-of-the} the signal sample is the one we used to perform
! 656: the measurement. The cuts here consist of $NN(\tau)>0.90$ for taus types 1 and 2,
! 657: $NN(\tau)>0.95$ for taus type 3, and at least one NN b-tag. This sample contains
! 658: a good amount of $t\bar{t}$ (19.7\% for types 1 and 2 and 8.6\% for type 3) as shown in Tables
! 659: \ref{b_and_tau_type1_2} and \ref{b_and_tau_type_3}. Next we show the plots of
! 660: the topological variables for this sample. The error bars represent the statistical uncertainties only.
! 661:
! 662: \begin{figure}[h]
! 663: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeI_II/aplan}
! 664: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeI_II/ht}
! 665: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeIII/aplan}
! 666: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeIII/ht}
! 667:
! 668: \caption{Distributions for aplanarity and $H_T$ in the signal sample for
! 669: tau of Types 1 and 2 (top) and taus of Type 3 (botton). The Kolmogorov-Smirnov (KS) probabilities are shown,
! 670: indicating the level of agreement.}
! 671:
! 672: %\label{fig:variables_type2_Std}
! 673: \end{figure}
! 674:
! 675: \newpage
! 676:
! 677: \begin{figure}[t]
! 678: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeI_II/cent}
! 679: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeI_II/spher}
! 680: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeIII/cent}
! 681: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeIII/spher}
! 682:
! 683: \caption{Distributions for centrality and sphericity in the signal sample for
! 684: tau of Types 1 and 2 (top) and taus of Type 3 (botton). The Kolmogorov-Smirnov (KS) probabilities are shown,
! 685: indicating the level of agreement.}
! 686: %\label{fig:variables_type2_Std}
! 687: \end{figure}
! 688:
! 689:
! 690: \begin{figure}[b]
! 691: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeI_II/sqrts}
! 692: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeI_II/costhetastar}
! 693: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeIII/sqrts}
! 694: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeIII/costhetastar}
! 695:
! 696: \caption{Distributions for $M_{jj\tau}$ and $cos(\theta^{*})$ in the signal sample for
! 697: tau of Types 1 and 2 (top) and taus of Type 3 (botton). The Kolmogorov-Smirnov (KS) probabilities are shown,
! 698: indicating the level of agreement.}
! 699: %\label{fig:variables_type2_Std}
! 700: \end{figure}
! 701:
! 702: \begin{figure}[t]
! 703: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeI_II/metl}
! 704: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeI_II/met}
! 705: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeIII/metl}
! 706: \includegraphics[scale=0.34]{CONTROLPLOTS/Std_TypeIII/met}
! 707:
! 708: \caption{Distributions for \met and $\not\!\! E_{T}$ significance significance in the signal sample for
! 709: tau of Types 1 and 2 (top) and taus of Type 3 (botton). The Kolmogorov-Smirnov (KS) probabilities are shown,
! 710: indicating the level of agreement.}
! 711: %\label{fig:variables_type2_Std}
! 712: \end{figure}
! 713:
! 714: \clearpage
! 715:
! 716: \subsection{\label{app:signalplots}b-veto control sample plots}
! 717:
! 718: The b-veto sample is the one used to test our QCD modelling \ref{sub:Results-of-the}. As it requires no
! 719: NN b-tags it is QCD-dominated and has a tiny amount of $t\bar{t}$ (1.9\% for types 1 and 2 and 0.7\% for type 3)
! 720: as shown in Tables \ref{bveto_type1_2} and \ref{b_veto_type_3}. It consists of an ideal sample to make sure
! 721: that the QCD modelling works and can be used in the measurement. Next we show the plots of
! 722: the topological variables for this sample. The error bars represent the statistical uncertainties only.
! 723:
! 724: \begin{figure}[h]
! 725: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeI_II/aplan}
! 726: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeI_II/ht}
! 727: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeIII/aplan}
! 728: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeIII/ht}
! 729:
! 730: \caption{Distributions for aplanarity and $H_T$ in the $b$-veto sample for
! 731: tau of Types 1 and 2 (top) and taus of Type 3 (botton). The Kolmogorov-Smirnov (KS) probabilities are shown,
! 732: indicating the level of agreement.}
! 733:
! 734: %\label{fig:variables_type2_bveto}
! 735: \end{figure}
! 736:
! 737: \newpage
! 738:
! 739: \begin{figure}[t]
! 740: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeI_II/cent}
! 741: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeI_II/spher}
! 742: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeIII/cent}
! 743: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeIII/spher}
! 744:
! 745: \caption{Distributions for centrality and sphericity in the $b$-veto sample for
! 746: tau of Types 1 and 2 (top) and taus of Type 3 (botton). The Kolmogorov-Smirnov (KS) probabilities are shown,
! 747: indicating the level of agreement.}
! 748:
! 749: %\label{fig:variables_type2_bveto}
! 750: \end{figure}
! 751:
! 752: \begin{figure}[b]
! 753: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeI_II/sqrts}
! 754: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeI_II/costhetastar}
! 755: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeIII/sqrts}
! 756: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeIII/costhetastar}
! 757:
! 758: \caption{Distributions for $M_{jj\tau}$ and $cos(\theta^{*})$ in the $b$-veto sample for
! 759: tau of Types 1 and 2 (top) and taus of Type 3 (botton). The Kolmogorov-Smirnov (KS) probabilities are shown,
! 760: indicating the level of agreement.}
! 761:
! 762: %\label{fig:variables_type2_bveto}
! 763: \end{figure}
! 764:
! 765:
! 766: \begin{figure}[t]
! 767: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeI_II/metl}
! 768: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeI_II/met}
! 769: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeIII/metl}
! 770: \includegraphics[scale=0.34]{CONTROLPLOTS/bveto_TypeIII/met}
! 771:
! 772: \caption{Distributions for \met and $\not\!\! E_{T}$ significance significance in the $b$-veto sample for
! 773: tau of Types 1 and 2 (top) and taus of Type 3 (botton). The Kolmogorov-Smirnov (KS) probabilities are shown,
! 774: indicating the level of agreement.}
1.1 uid12904 775:
776: %\label{fig:variables_type2_bveto}
777: \end{figure}
778:
779: \clearpage
780:
781:
1.2 ! uid12904 782: \section{\label{app:xsec_nocont}Cross measurement without accounting for signal contamination in the background sample.}
! 783:
! 784: \noindent In this appendix we show results of cross section measurements for both NNelec $>$ 0.9 and no NNelec cut
! 785: applied when the signal contamination in the loose-tight tau region is not taken into account. They serve as a
! 786: complement to the discussion presented in Section \ref{sub:xsect}.
1.1 uid12904 787:
1.2 ! uid12904 788: \subsection{\label{sub:xsectA}Results for Set = METsig, {$H_{T}$}, topmassl, aplan, Mjjtau, METsig $>$ 4.0, lumi = 4951.86/pb, VC jets and
1.1 uid12904 789: NNelec $>$ 0.9}
790:
791: Table below summarizes the number of events in each channel after final selection.
792:
793:
794: \begin{table}[h]
795: \caption{Final number of events in the two analysis channels.}
796: %\begin{ruledtabular}
797: \begin{tabular}{cccccc}
798: \hline
799: &$\tau$ type I,II
800: &$\tau$ type I,II (fitted)
801: &$\tau$ type III
802: &$\tau$ type III (fitted)&\\
803: \hline
804: data&
805: 386 &
806: &
807: 459 &
808: &\\
809: $t\overline{t}\rightarrow\tau+jets$&
810: 72.04 $\pm$ 0.53&
811: &
812: 38.82 $\pm$ 0.39&\\
813: $t\overline{t}\rightarrow e+jets$&
814: 38.35 $\pm$ 0.36&
815: &
816: 6.52 $\pm$ 0.16&
817: &\\
818: $t\overline{t}\rightarrow\mu+jets$&
819: 4.81 $\pm$ 0.14&
820: &
821: 5.14 $\pm$ 0.14&
822: &\\
823: $t\overline{t}\rightarrow l+l$&
824: 6.02 $\pm$ 0.07&
825: &
826: 4.20 $\pm$ 0.06&
827: &\\
828: $t\overline{t}$ total MC&
829: &
830: 121.22 $\pm$ 0.43&
831: &
832: 54.68 $\pm$ 0.20&\\
833: $t\overline{t}$ total fitted&
834: &
835: 133.04 $\pm$ 17.09&
836: &
837: 33.12 $\pm$ 15.04&\\
838: $W$+jets&
839: 17.82 $\pm$ 0.33&
840: &
841: 11.26 $\pm$ 0.23&
842: &\\
843: $Z$+jets&
844: 2.78 $\pm$ 0.14&
845: &
846: 2.39 $\pm$ 0.12&
847: &\\
848: QCD&
849: &
850: 232.35 $\pm$ 17.09&
851: &
852: 412.22 $\pm$ 15.04\\
853: Signal significance&
854: &
855: 6.77&
856: &
857: 1.54
858: &\\
859: S/B ratio&
860: &
861: 0.52&
862: &
863: 0.08\\
864: \end{tabular}
865: %\end{ruledtabular}
866: \label{event yeild summary}
867: \end{table}
868:
869:
870: Without taking into account the signal contamination the result is (only statistical uncertainties are shown)
871:
872: \begin{center}$\tau$+jets types 1 and 2 cross section: \[\sigma (t\overline{t}) =
873: 8.05\;\;_{-1.02}^{+1.04}\;\;({\textrm{stat}})\;\;\pm 0.3\;\;({\textrm{lumi}})\;\; \rm{pb,}\]
874: \par\end{center}
875:
876: \begin{center}$\tau$+jets type 3 cross section: \[\sigma (t\overline{t}) =
877: 4.24\;\;_{-1.80}^{+1.94}\;\;({\textrm{stat}})\;\;\pm 0.3\;\;({\textrm{lumi}})\;\; \rm{pb,}\]
878: \par\end{center}
879:
880:
881:
882: \begin{center}Combined cross section: \[\sigma (t\overline{t}) =
883: 7.26\;\;_{-0.92}^{+0.92}\;\;({\textrm{stat}})\;\;\pm 0.3\;\;({\textrm{lumi}})\;\; \rm{pb,}\]
884: \par\end{center}
885:
886:
887: \clearpage
888:
889:
1.2 ! uid12904 890: \subsection{\label{sub:xsectA}Results for Set = Set = METsig, {$H_{T}$}, topmassl, aplan, Mjjtau, METsig $>$ 4.0, lumi = 4951.86/pb, VC jets and no NNelec cut}
1.1 uid12904 891:
892: Table below summarizes the number of events in each channel after final selection.
893:
894:
895: \begin{table}[h]
896: \caption{Final number of events in the two analysis channels.}
897: %\begin{ruledtabular}
898: \begin{tabular}{cccccc}
899: \hline
900: &$\tau$ type I,II
901: &$\tau$ type I,II (fitted)
902: &$\tau$ type III
903: &$\tau$ type III (fitted)&\\
904: \hline
905: data&
906: 583 &
907: &
908: 459 &
909: &\\
910: $t\overline{t}\rightarrow\tau+jets$&
911: 85.46 $\pm$ 0.58&
912: &
913: 38.82 $\pm$ 0.39&\\
914: $t\overline{t}\rightarrow e+jets$&
915: 175.23 $\pm$ 0.85&
916: &
917: 6.52 $\pm$ 0.16&
918: &\\
919: $t\overline{t}\rightarrow\mu+jets$&
920: 8.98 $\pm$ 0.19&
921: &
922: 5.14 $\pm$ 0.14&
923: &\\
924: $t\overline{t}\rightarrow l+l$&
925: 12.62 $\pm$ 0.10&
926: &
927: 4.18 $\pm$ 0.06&
928: &\\
929: $t\overline{t}$ total MC&
930: &
931: 282.27 $\pm$ 1.05&
932: &
933: 54.67 $\pm$ 0.41&\\
934: $t\overline{t}$ total fitted&
935: &
936: 260.71 $\pm$ 20.74&
937: &
938: 35.73 $\pm$ 15.28&\\
939: $W$+jets&
940: 39.65 $\pm$ 0.50&
941: &
942: 11.26 $\pm$ 0.25&
943: &\\
944: $Z$+jets&
945: 4.56 $\pm$ 0.10&
946: &
947: 2.38 $\pm$ 0.11&
948: &\\
949: QCD&
950: &
951: 278.04 $\pm$ 20.74&
952: &
953: 409.62 $\pm$ 15.28\\
954: Signal significance&
955: &
956: 10.80&
957: &
958: 1.67
959: &\\
960: S/B ratio&
961: &
962: 0.80&
963: &
964: 0.08\\
965: \end{tabular}
966: %\end{ruledtabular}
967: \label{event yeild summary}
968: \end{table}
969: %
970:
971:
972: Without taking into account the signal contamination the result is (only statistical uncertainties are shown)
973:
974: \begin{center}$\tau$+jets types 1 and 2 cross section: \[\sigma (t\overline{t}) =
975: 6.47\;\;_{-0.53}^{+0.53}\;\;({\textrm{stat}})\;\;\pm 0.3\;\;({\textrm{lumi}})\;\; \rm{pb,}\]
976: \par\end{center}
977:
978: \begin{center}$\tau$+jets type 3 cross section: \[\sigma (t\overline{t}) =
979: 4.58\;\;_{-1.85}^{+1.96}\;\;({\textrm{stat}})\;\;\pm 0.3\;\;({\textrm{lumi}})\;\; \rm{pb,}\]
980: \par\end{center}
981:
982:
983:
984: \begin{center}Combined cross section: \[\sigma (t\overline{t}) =
985: 6.35\;\;_{-0.51}^{+0.51}\;\;({\textrm{stat}})\;\;\pm 0.3\;\;({\textrm{lumi}})\;\; \rm{pb,}\]
986: \par\end{center}
987:
988:
989:
990: %\section{Appendix A}
991:
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