This is a set of ntuples containing details of the aleph SM scan using
the LHWG inputs.  Contained in the file are:

Ntuples:

ID: 2000   (Individual channel details)

Hmass      (SM Higgs mass)
Channel    (Channel number)
CsbExp     (Expected Csb for bkg - mean)
CbExp      (Expected Cb for bkg - mean)
CsbObs     (Observed Csb for bkg)
CbObs      (Observed Cb for bkg)
logLR      (observed log Likelihood Ratio)
b01        (background expectation)
s01        (signal expectation)
Cratio     (Expected Cs=Csb/Cb for bkg - mean)

Note:  For this scan, channel numbers are not conserved between
mass points-- channels with zero signal were removed.  To follow
a given channel, you are best off identifying it by background level.
This scan has also not implemented medians for individual channels.

ID: 3100   (Combined results)

Hmass      (SM Higgs mass)
csbinfm0   (Expected Csb for bkg - median)
cbinfm0    (Expected Cb for bkg - median)
logLR      (Observed log Likelihood Ratio)
CsbExp     (Expected Csb for bkg - mean)
CbExp      (Expected Cb for bkg - mean)
CsbObs     (Observed Csb for bkg)
CbObs      (Observed Cb for bkg)
stot       (signal expectation)
btot       (background expectation)
Cratio     (Expected Cs=Csb/Cb for bkg - mean)
Ssbexp     (Expected significance for signal over bkg)
Sbexp      (Expected significance for bkg over bkg (=0))
Ssbobs     (Observed significance for data for s+b hypothesis)
Sbobs      (Observed significance for data for bkg hypothesis)

Note: Significance is just a new y axis presentation.  0 indicates
good agreement, positive numbers are excesses and negative numbers
are deficits, expressed in number of standard deviations.  The
information content is essentially the same as in the confidence levels,
but it is presented in non-specialist terms.  For example, we can
see that with these inputs, we have approximately a 2-sigma excess
over background at 115 GeV, and that we would expect a 5 sigma excess
from a Higgs signal at ~105 GeV.