Mehulkumar Shiroya authored Nov 23, 2021 and Florian Uhlig committed Nov 25, 2021

STS v21h: The geometry has the target positioned at -4 cm. It can be used with the beampipe 40mm diameter upstream side
and 104mm diameter downstream side. It has a beampipe flange on the back-side of the STS wall.
In addition, the geometry has a sensor thickness 320 um which is similar thickness of the real silicon sensors purchased from the Hamamatsu Photonics
for the use in the real experiment.
Furthermore,the mico-cable is defined as a single volume attached to the silicon sensors. Micro-cable thickness (320 um) is choosen and
the material Manganese is taken based on the calculation done by taking the current microcable design, thickness and its material.

STS v21i: The geometry has the target positioned at -44 cm from the center of the magnet. It can be used with the beampipe 40mm diameter upstream side
and 104mm diameter downstream side. It doesn't have a beam-pipe flange on the back-side of the wall.
In addition, the geometry has a sensor thickness 320 um which is similar thickness of the real silicon sensors purchased from the Hamamatsu >
for the use in the real experiment.
Furthermore,the mico-cable is defined as a single volume attached to the silicon sensors. Micro-cable thickness (320 um) is choosen and
the material Manganese is taken based on the calculation done by taking the current microcable design, thickness and its material.

v21f: STS geometry is similar to the version v21b. The target position considered from -4 cm.
The geometry can be used with the beampipe with diameter 40 mm upstream side and 104 mm downstream side.
The geometry has beampipe flange on the back-side of the wall.

v21g: STS geometry is similar to the version v21e. The target position is at -40 cm considering global origin
from the center of magnet. The STS local coordinate is from the last station.
The geometry can be used with the beampipe with diameter 40 mm upstream side and 104 mm downstream side.

In both geometry, the STS box and the beam pipe flange is made of Carbon fiber: The material has 70% carbon fiber with
density 1.75 g/cm3 and epoxy resin (30%) with density 1.2 g/cm3. The material is defined in media.geo file as
STS_CarbonFiber_21.

Change in tranformation from global origin (centre of magnet) to local origin of sts (last station) to a 59.5cm shift.
Front face of sts from a target placed at 44cm is now 1.6 cm.

Volker Friese authored Nov 22, 2021 and Florian Uhlig committed Nov 22, 2021

Integration of cbm::algo::EventBuilder in the FairRoot run/task framework, with the new task CbmTaskBuildEvents. Included into regular testing. Refs #2271.

Volker Friese authored Nov 19, 2021 and Pierre-Alain Loizeau committed Nov 19, 2021

Enabled setting parameters for single STS ASICs. Expanded ASIC parameter container by time offset and coefficients for walk correction.

Dominik Smith authored Nov 05, 2021 and Florian Uhlig committed Nov 19, 2021

CbmTrdHitProducerQa: Fetching TrdPoints and MC tracks from CbmMCDataManager instead of FairRootManager.

Dominik Smith authored Nov 02, 2021 and Florian Uhlig committed Nov 19, 2021

- Histograms are now produced separately for residual and pull distributions.
- Enabled auto-extension of histogram axes.
- TrdPoint positions used are now mean of 'in' and 'out' values.
- Added residual and pull for hit times.
- Removed some root data types.

Dominik Smith authored Oct 01, 2021 and Florian Uhlig committed Nov 19, 2021

CbmTrdHitProducerQa: Histograms are now produced for a pre-selected number of planes (set by user, default = 4). Added CbmQaCanvas containers for all histograms (layer-wise).