[Olympus] Acceptance Simulations

Inti Lehmann inti.lehmann at glasgow.ac.uk
Thu Nov 22 05:52:18 EST 2012 

Hi Axel and Michael,

I'm lost now: What are you looking for or trying to prove, Michael? 

In the corners of the TOFs we have overlap. In the flat sections we have small gaps of possibly 2mm. Everybody can do a back-of-the-envelope calculation to realise that the loss of acceptance due to this gaps will be at the 1% level. It is the worst in small angles as the gaps are most parallel to particle tracks.The gaps may be slightly different from place to place, but there is nothing one can learn with MC about a reality which is not modelled.

Though I repeat myself, I say it again. Any scintillator of this size which exhibits an efficiency below 99% is simply broken! If I were you I would not show Joachim Mnich or anyone else plots which insinuate that you expect scintillators with lower efficiency. Anyone would tell you to go and replace them rather than discussing systematic effects or changing the field.

My feeling is that the only systematic effect due to the TOFs is due to the different e+ e- acceptance at the forward end. This can probably modelled rather well. Efficiency effects may be serious but I'm quite sure they will be driven by the WC. Independently on the cause one could just study scenarios with changing efficiencies in different regions. If I were you I would at doing that over the WC active area rather than the TOFs.

Hope to have helped!

Cheers,
Inti







On 21 Nov 2012, at 05:18, Michael Kohl wrote:

> Hi Axel,
> thank you.
> Now these double ratios look like they were done with the white generator?
> However, the latest plot file "tof_gaps.pdf" in my possession for the 
> single-polarity ratios still has the large errors at large angles. Could 
> you update them, too?
> And add a plot for the yields themselves (from which the ratios are 
> formed, maybe all four with different colors in one panel, i.e. three 
> panels for 0, 1, and 2cm gaps).
> 
> Also it would be good for any of the ratios to zoom into the y range to 
> 1.0 +-10% in order to see the deviations from one in more detail.
> 
> So it looks like there are some good washout effects at work, in 
> particular if the efficiency structures are smaller than the "washout 
> scale", which could likely be of order of the extended target length. What 
> would be interesting next is to study along the lines of Stanislav's 
> proposal to see what happens when entire TOF bars or combinations of TOF 
> bars are less efficient than others. Here, the benefit 
> from washing out structures may be less so, because the localized 
> efficiency structures would be of similar order like the "washout scale". 
> Similarly, this could be the case for inefficient cells in the WC. How 
> much bigger are the corrections for single ratios than for the fourfold 
> ratios?
> 
> The list of things to look at can obviously be extended for many aspects. 
> What we shall think about is, and this was requested by J. Mnich, what is 
> the best set of measurements other than B+ running that should be done 
> toward the end of the OLYMPUS run that can eventually help us verifying 
> and tuning the MC, in order to achieve better than 1% systematics 
> everywhere.
> 
> Thank you,
>   Michael
> 
> 
> 
> On Tue, 20 Nov 2012, Axel Schmidt wrote:
> 
>> Hi Michael,
>> 	I'm attaching the plot of the acceptance double ratio with all four configurations as was initially proposed.  One can see that even with gaps in the ToFs, the ratio remains very close to 1.
>> 
>> 	I have done some studies with different magnetic field strengths (all with positive polarity).  None of the results were so different than those at 5000 A, so I did not find them so intriguing.
>> 
>> Cheers,
>> Axel
>> 
>> 
> 
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