cmsnotes/StopSearch/CR2.tex


\subsection{Single Lepton Top MC Modelling Validation from CR2}
\label{sec:cr2}


The \mt\ tail for single-lepton top events (\ttsl\ and single top) is dominated by jet resolution effects. The \W\ cannot be far off-shell because $\mW < \mtop$.
The modeling of the \mt\ tail from jet resolution effects is studied
using \zjets\ data and MC samples. 

\Z\ events are selected by requiring exactly 2 good leptons (satisfying ID
and isolation requirements) and requiring the \mll\ to be in the range
$81-101$ GeV. 
Events with additional isolated tracks are vetoed, as in Section~\ref{sec:tkveto}.
To reduce \ttbar\ backgrounds, events with a CSVM tag %H
are removed.
The negative lepton is treated as a neutrino and so is added to the MET: \met\ $\rightarrow$ \pt(\Lepm) + \met, 
and the \mt\ is recalculated with the positive lepton \mt(\Lepp, \met).
The resulting ``pseudo-\mt'' is dominated by jet resolution effects, since no off-shell 
\Z\ production enters the sample due to the \mll\ requirement.
This section describes how well the MC predicts the tail of ``pseudo-\mt''. 

The underlying distributions are shown in Fig.~\ref{fig:cr2met}
and~\ref{fig:cr2mtrest}.    Just as in CR1, there is an excess in the
tails, but there are insufficient events to derive scale factors.
% for $\met\ > 150$~GeV.


%We then perform the exact same type of Data/MC comparison and analysis as 
%described for CR1 in Section~\ref{sec:cr1}.  For CR1 we collected
%the data/MC tail information in 
%Table~\ref{tab:cr1yields} ; the equivalent for CR2 is
%Table~\ref{tab:cr2yields}
%(for CR2 the statistics are not sufficient to split electrons and muons).
%The last line of Table~\ref{tab:cr2yields} gives the data/MC scale factor
%for the \ttbar\ lepton $+$ jets $M_T$ tail ($SFR_{top}$).  This is
%calculated in the same way as $SFR_{wjets}$ of Table~\ref{tab:cr1yields}.


\begin{table}[!h]
\begin{center}
{\footnotesize
\begin{tabular}{l||c|c||c|c|c|c|c}
\hline
Sample              & CR2PRESEL0 &CR2PRESEL1 & CR2A & CR2B & CR2C &
CR2D & CR2E \\
\hline
\hline
MC                & $36 \pm 2$ & $30 \pm 2$ & $18 \pm 1$ & $30 \pm 2$ & $13 \pm 1$ & $5 \pm 0$ & $2 \pm 0$ \\
Data              & $56$ & $43$ & $32$ & $40$ & $21$ & $12$ & $2$ \\
\hline
Data/MC           & $1.56 \pm 0.23$ & $1.44 \pm 0.24$ & $1.77 \pm 0.34$ & $1.32 \pm 0.22$ & $1.65 \pm 0.37$ & $2.65 \pm 0.79$ & $0.99 \pm 0.71$ \\
\hline
\hline
\hline
DY MC             & $27 \pm 2$ & $23 \pm 2$ & $14 \pm 2$ & $25 \pm 3$ & $11 \pm 2$ & $3 \pm 1$ & $1 \pm 1$ \\
DY Data           & $47 \pm 8$ & $36 \pm 7$ & $28 \pm 6$ & $35 \pm 6$ & $19 \pm 5$ & $11 \pm 3$ & $1 \pm 1$ \\
\hline
DY Data/MC        & $1.75 \pm 0.31$ & $1.58 \pm 0.32$ & $2.00 \pm 0.47$ & $1.38 \pm 0.31$ & $1.78 \pm 0.56$ & $3.29 \pm 1.73$ & $0.98 \pm 1.20$ \\
\hline
\hline
\hline
$SFR_{top}$       & $1.66 \pm 0.40$ & $1.51 \pm 0.35$ & $1.89 \pm 0.56$ & $1.35 \pm 0.28$ & $1.71 \pm 0.51$ & $2.97 \pm 1.26$ & $0.98 \pm 0.71$ \\
\hline
\end{tabular}}
\caption{ Yields in \mt\ tail comparing the \zjets\ MC prediction (after
  applying SFs) to data without subtracting the non-\zjets\ components (top table) and with subtracting the non-\zjets\ components (bottom table). 
  CR2PRESEL refers to a sample with $\met>50$ GeV and $\mt>150$ GeV.
\label{tab:cr2yields}}
\end{center}
\end{table}


\begin{figure}[hbt]
  \begin{center}
%       \includegraphics[width=0.5\linewidth]{plots/CR2plots/met_scaled_nj4_emucomb.pdf}%
        \includegraphics[width=0.5\linewidth]{plots/CR2plots/met_lepcor_scaled_nj4_emucomb.pdf}%
        \includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_nj4_emucomb.pdf}
        \includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_met50_nj4_emucomb.pdf}%
        \includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_met100_nj4_emucomb.pdf}

    \caption{
      Comparison of the pseudo-\met\ (top, left), pseudo-\mt\ (top,
      right and bottom) distributions in data vs. MC for events
      satisfying the requirements of CR2, combining both the muon and
      electron channels. The pseudo-\mt\ distributions are shown
      before any additional requirements (top, right) and after
      requiring pseudo-\met $>$50 GeV (bottom, left) and pseudo-\met
      $>$ 100 GeV (bottom, right) .
\label{fig:cr2met} 
}  
      \end{center}
\end{figure}

\begin{figure}[hbt]
  \begin{center}
        \includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_met150_nj4_emucomb.pdf}%
        \includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_met200_nj4_emucomb.pdf}
        \includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_met250_nj4_emucomb.pdf}%
        \includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_met300_nj4_emucomb.pdf}
    \caption{
      Comparison of the \mt\ distribution in data vs. MC for events
      satisfying the requirements of CR2, combining both the muon and
      electron channels. The pseudo-\met\ requirements used are
      150 GeV (top, left), 200 GeV (top, right), 250 GeV (bottom,
      left) and 300 GeV (bottom, right).
\label{fig:cr2mtrest} 
}  
      \end{center}
\end{figure}
\clearpage
Revision:	1.8
Committed:	Thu Oct 18 21:21:56 2012 UTC (12 years, 6 months ago) by linacre
Content type:	application/x-tex
Branch:	MAIN
Changes since 1.7:	+16 -12 lines
Log Message:	new top tail-to-peak method
#	User	Rev	Content
1	claudioc	1.1
2			\subsection{Single Lepton Top MC Modelling Validation from CR2}
3			\label{sec:cr2}
4
5
6			The \mt\ tail for single-lepton top events (\ttsl\ and single top) is dominated by jet resolution effects. The \W\ cannot be far off-shell because $\mW < \mtop$.
7	claudioc	1.6	The modeling of the \mt\ tail from jet resolution effects is studied
8			using \zjets\ data and MC samples.
9
10	linacre	1.8	\Z\ events are selected by requiring exactly 2 good leptons (satisfying ID
11	claudioc	1.6	and isolation requirements) and requiring the \mll\ to be in the range
12	linacre	1.8	$81-101$ GeV.
13			Events with additional isolated tracks are vetoed, as in Section~\ref{sec:tkveto}.
14			To reduce \ttbar\ backgrounds, events with a CSVM tag %H
15	claudioc	1.6	are removed.
16	claudioc	1.1	The negative lepton is treated as a neutrino and so is added to the MET: \met\ $\rightarrow$ \pt(\Lepm) + \met,
17			and the \mt\ is recalculated with the positive lepton \mt(\Lepp, \met).
18			The resulting ``pseudo-\mt'' is dominated by jet resolution effects, since no off-shell
19			\Z\ production enters the sample due to the \mll\ requirement.
20			This section describes how well the MC predicts the tail of ``pseudo-\mt''.
21
22			The underlying distributions are shown in Fig.~\ref{fig:cr2met}
23	claudioc	1.6	and~\ref{fig:cr2mtrest}. Just as in CR1, there is an excess in the
24	linacre	1.8	tails, but there are insufficient events to derive scale factors.
25			% for $\met\ > 150$~GeV.
26	claudioc	1.6
27	linacre	1.8
28			%We then perform the exact same type of Data/MC comparison and analysis as
29			%described for CR1 in Section~\ref{sec:cr1}. For CR1 we collected
30			%the data/MC tail information in
31			%Table~\ref{tab:cr1yields} ; the equivalent for CR2 is
32			%Table~\ref{tab:cr2yields}
33			%(for CR2 the statistics are not sufficient to split electrons and muons).
34			%The last line of Table~\ref{tab:cr2yields} gives the data/MC scale factor
35			%for the \ttbar\ lepton $+$ jets $M_T$ tail ($SFR_{top}$). This is
36			%calculated in the same way as $SFR_{wjets}$ of Table~\ref{tab:cr1yields}.
37	claudioc	1.1
38
39			\begin{table}[!h]
40			\begin{center}
41	vimartin	1.2	{\footnotesize
42			\begin{tabular}{l\|\|c\|c\|\|c\|c\|c\|c\|c}
43	claudioc	1.1	\hline
44	vimartin	1.2	Sample & CR2PRESEL0 &CR2PRESEL1 & CR2A & CR2B & CR2C &
45	vimartin	1.4	CR2D & CR2E \\
46	claudioc	1.1	\hline
47			\hline
48	vimartin	1.4	MC & $36 \pm 2$ & $30 \pm 2$ & $18 \pm 1$ & $30 \pm 2$ & $13 \pm 1$ & $5 \pm 0$ & $2 \pm 0$ \\
49			Data & $56$ & $43$ & $32$ & $40$ & $21$ & $12$ & $2$ \\
50			\hline
51			Data/MC & $1.56 \pm 0.23$ & $1.44 \pm 0.24$ & $1.77 \pm 0.34$ & $1.32 \pm 0.22$ & $1.65 \pm 0.37$ & $2.65 \pm 0.79$ & $0.99 \pm 0.71$ \\
52			\hline
53	claudioc	1.1	\hline
54	vimartin	1.3	\hline
55	vimartin	1.4	DY MC & $27 \pm 2$ & $23 \pm 2$ & $14 \pm 2$ & $25 \pm 3$ & $11 \pm 2$ & $3 \pm 1$ & $1 \pm 1$ \\
56			DY Data & $47 \pm 8$ & $36 \pm 7$ & $28 \pm 6$ & $35 \pm 6$ & $19 \pm 5$ & $11 \pm 3$ & $1 \pm 1$ \\
57	vimartin	1.3	\hline
58	vimartin	1.4	DY Data/MC & $1.75 \pm 0.31$ & $1.58 \pm 0.32$ & $2.00 \pm 0.47$ & $1.38 \pm 0.31$ & $1.78 \pm 0.56$ & $3.29 \pm 1.73$ & $0.98 \pm 1.20$ \\
59	vimartin	1.3	\hline
60			\hline
61			\hline
62	vimartin	1.5	$SFR_{top}$ & $1.66 \pm 0.40$ & $1.51 \pm 0.35$ & $1.89 \pm 0.56$ & $1.35 \pm 0.28$ & $1.71 \pm 0.51$ & $2.97 \pm 1.26$ & $0.98 \pm 0.71$ \\
63	claudioc	1.1	\hline
64	vimartin	1.2	\end{tabular}}
65	vimartin	1.4	\caption{ Yields in \mt\ tail comparing the \zjets\ MC prediction (after
66	benhoob	1.7	applying SFs) to data without subtracting the non-\zjets\ components (top table) and with subtracting the non-\zjets\ components (bottom table).
67	vimartin	1.4	CR2PRESEL refers to a sample with $\met>50$ GeV and $\mt>150$ GeV.
68	claudioc	1.1	\label{tab:cr2yields}}
69			\end{center}
70			\end{table}
71
72	vimartin	1.3
73	claudioc	1.1	\begin{figure}[hbt]
74			\begin{center}
75	vimartin	1.2	% \includegraphics[width=0.5\linewidth]{plots/CR2plots/met_scaled_nj4_emucomb.pdf}%
76			\includegraphics[width=0.5\linewidth]{plots/CR2plots/met_lepcor_scaled_nj4_emucomb.pdf}%
77			\includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_nj4_emucomb.pdf}
78			\includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_met50_nj4_emucomb.pdf}%
79			\includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_met100_nj4_emucomb.pdf}
80
81	claudioc	1.1	\caption{
82	benhoob	1.7	Comparison of the pseudo-\met\ (top, left), pseudo-\mt\ (top,
83	vimartin	1.2	right and bottom) distributions in data vs. MC for events
84	claudioc	1.1	satisfying the requirements of CR2, combining both the muon and
85	benhoob	1.7	electron channels. The pseudo-\mt\ distributions are shown
86	vimartin	1.2	before any additional requirements (top, right) and after
87	benhoob	1.7	requiring pseudo-\met $>$50 GeV (bottom, left) and pseudo-\met
88	claudioc	1.6	$>$ 100 GeV (bottom, right) .
89	claudioc	1.1	\label{fig:cr2met}
90			}
91			\end{center}
92			\end{figure}
93
94			\begin{figure}[hbt]
95			\begin{center}
96	vimartin	1.2	\includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_met150_nj4_emucomb.pdf}%
97			\includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_met200_nj4_emucomb.pdf}
98			\includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_met250_nj4_emucomb.pdf}%
99			\includegraphics[width=0.5\linewidth]{plots/CR2plots/mt_lepcor_scaled_met300_nj4_emucomb.pdf}
100	claudioc	1.1	\caption{
101			Comparison of the \mt\ distribution in data vs. MC for events
102			satisfying the requirements of CR2, combining both the muon and
103			electron channels. The pseudo-\met\ requirements used are
104	vimartin	1.2	150 GeV (top, left), 200 GeV (top, right), 250 GeV (bottom,
105			left) and 300 GeV (bottom, right).
106	claudioc	1.1	\label{fig:cr2mtrest}
107			}
108			\end{center}
109			\end{figure}
110	benhoob	1.7	\clearpage