Commit 929a1468 authored by cbm's avatar cbm

optimize trd and much posn in mcbm2022, refs #2306

parent 1b9edab7
MUCH geometry created with create_MUCH_geometry_v20a_mcbm.C
Build a mMUCH setup for mCBM with 2 GEM.
10 mm thick Al plates are used for support and cooling in the GEM modules.
Drift and read-out PCBs (copper coated G10 plates) inserted for realistic material budget for both GEM and RPC modules.
No of Modules: 2 ( GEM )
Position of Modules Z [cm]: 65.7 88.7
Placement of Modules:
Module X [cm] Y [cm]
----------------------
1 7.2 24.53
2 7.2 24.53
----------------------
Al Cooling Plate Thickness [cm]: 1 1
Active Volume Thickness [cm]: 0.3 0.3
GEM Module:
7.5 cm
......... |
........... |
............. |
............... |
................. |
................... |
..................... |
....................... 80 cm
......................... |
........................... |
............................. |
............................... |
................................. |
................................... |
..................................... |
....................................... |
40 cm
MUCH geometry created with create_MUCH_geometry_v22b_mcbm.C
Build a mMUCH setup for mCBM with 1 GEM.
10 mm thick Al plates are used for support and cooling in the GEM modules.
Drift and read-out PCBs (copper coated G10 plates) inserted for realistic material budget for both GEM and RPC modules.
No of Modules: 2 ( GEM )
Position of Modules Z [cm]: 65.7 118.7
Placement of Modules:
Module X [cm] Y [cm]
----------------------
1 7.2 24.53
2 7.2 24.53
----------------------
Al Cooling Plate Thickness [cm]: 1 1
Active Volume Thickness [cm]: 0.3 0.3
GEM Module:
7.5 cm
......... |
........... |
............. |
............... |
................. |
................... |
..................... |
....................... 80 cm
......................... |
........................... |
............................. |
............................... |
................................. |
................................... |
..................................... |
....................................... |
40 cm
......@@ -59,7 +59,7 @@ void setup_mcbm_beam_2022_04() {
// TString mvdGeoTag = "v18b_mcbm";
TString stsGeoTag = "v20e_mcbm";
// TString muchGeoTag = "v22a_mcbm"; // 2 layers
TString trdGeoTag = "v21b_mcbm"; // 2022
TString trdGeoTag = "v22a_mcbm"; // 2022
TString tofGeoTag = "v20d_mcbm"; // TOF double wall
TString richGeoTag = "v20d_mcbm"; // geometry provided by RICH group
TString psdGeoTag = "v20a_mcbm"; // at 25 degree, below the beampipe
......
......@@ -59,7 +59,7 @@ void setup_mcbm_beam_2022_05() {
// TString mvdGeoTag = "v18b_mcbm";
TString stsGeoTag = "v20e_mcbm";
// TString muchGeoTag = "v22a_mcbm"; // 2 layers
TString trdGeoTag = "v20b_mcbm"; // 2022
TString trdGeoTag = "v22b_mcbm"; // 2022
TString tofGeoTag = "v20d_mcbm"; // TOF double wall
TString richGeoTag = "v20d_mcbm"; // geometry provided by RICH group
TString psdGeoTag = "v20a_mcbm"; // at 25 degree, below the beampipe
......@@ -83,7 +83,7 @@ void setup_mcbm_beam_2022_05() {
setup->SetModule(ECbmModuleId::kPipe, pipeGeoTag);
// setup->SetModule(ECbmModuleId::kMvd, mvdGeoTag); // skip mvd
setup->SetModule(ECbmModuleId::kSts, stsGeoTag);
// setup->SetModule(ECbmModuleId::kMuch, muchGeoTag);
// setup->SetModule(ECbmModuleId::kMuch, muchGeoTag);
setup->SetModule(ECbmModuleId::kTrd, trdGeoTag);
setup->SetModule(ECbmModuleId::kTof, tofGeoTag);
setup->SetModule(ECbmModuleId::kRich, richGeoTag);
......
/** ROOT macro to define the CBM setup sis18_mcbm
**
** @author Volker Friese <v.friese@gsi.de>
** @author David Emschermann <d.emschermann@gsi.de>
** @date 5 February 2016
**
**/
// clang-format off
// 2021-10-03 - SR - setup for 2022 beamtime for the study of lambda physics
// 2021-09-28 - DE - surveyed position of TRD v21b, TOF v21d and RICH v21a
// 2020-08-17 - DE - add TRD v21a, add TOF v21c, disable MUCH v20a
// 2020-05-26 - DE - use RICH v20d which moved according to TOF v20b
// 2020-05-25 - DE - use TRD v20b with 2 modules and support frame for 2021
// 2020-05-22 - DE - use platform v20a with measured size of support table
// 2020-05-12 - DE - make mRICH v20b (without window) the new default
// 2020-03-11 - DE - prepare setup for mCBM Spring 2021 beamtime
// 2020-03-11 - DE - prepare setup for mCBM May 2020 beamtime
// 2020-03-11 - DE - prepare setup for mCBM March 2020 beamtime
// 2019-12-20 - FU - use the new pipe/targetbox geometry which consists of
// root files which are both passed to to CbmSetup
// 2019-11-28 - DE - move mTOF v19b +12 cm in x direction for the Nov 2019 run
// 2019-11-15 - DE - use mSTS v19b with single module in the top left of station 0
// 2019-08-15 - DE - use mCBM targetbox as pipe v19b
// 2019-08-12 - DE - use mSTS v19a
// 2019-08-08 - FU - use mMUCH v19a
// 2019-08-02 - DE - use pipe v19a with flange position at z=610 mm
// 2019-07-31 - DE - add TOF v18m=v19a geometry - provided by the TOF group
// 2019-07-31 - DE - add RICH v19a geometry - provided by the RICH group
// 2019-03-15 - DE - this is supposed to be the start version of mCBM in March 2019
// 2018-08-24 - DE - this is supposed to be the start version of mCBM in 2018
// 2018-06-27 - DE - set flipped mTOF v18j geometry as new default
// 2018-05-24 - DE - place 20deg_long setup back at 25 degrees, see issue #1078
// 2018-02-27 - DE - use mTRD v18o to fix redmine issue #1046 with tracking
// 2017-12-11 - DE - enable mBUCH v18m
// 2017-12-04 - DE - add mPSD to mCBM setup
// 2017-11-22 - DE - use TRD v17n with 22 cm spacing from CAD
// 2017-11-17 - DE - set aerogel mRICH v18d as default
// 2017-11-10 - DE - switch to mMUCH v18e with Mv2 dimensions
// 2017-11-03 - DE - add long setup, (acceptance matching +-12 degrees from mSTS)
// 2017-11-02 - DE - add common support table v18c
// 2017-11-02 - DE - include mBUCH with mTRD v18j
// 2017-10-23 - DE - use mMUCH with vertically aligned left rim
// 2017-10-18 - DE - use mTOF v18h with vertical orientation
// 2017-10-16 - DE - use 20 degree beampipe
// 2017-06-03 - DE - add RICH v18a_mcbm
// 2017-05-02 - DE - switch back to 5x5 RPC TOF
// 2017-05-02 - DE - skip MVD in the initial setup
// 2016-02-05 - VF - Replaces former sis18_mcbm_setup.C,
// now using the CbmSetup class.
// 2015-06-18 - DE - mCBM @ SIS18 setup
void setup_mcbm_beam_2022_03() {
// ----- Geometry Tags --------------------------------------------------
TString platGeoTag = "v20a_mcbm"; // 2020 // support table
TString pipeGeoTag = "v19f_mcbm"; // pipe after target box
// TString mvdGeoTag = "v18b_mcbm";
TString stsGeoTag = "v20e_mcbm";
TString muchGeoTag = "v22b_mcbm"; // 1 layer
TString trdGeoTag = "v22a_mcbm"; // 2022
TString tofGeoTag = "v20d_mcbm"; // TOF double wall
TString richGeoTag = "v20d_mcbm"; // geometry provided by RICH group
TString psdGeoTag = "v20a_mcbm"; // at 25 degree, below the beampipe
// ------------------------------------------------------------------------
// ----- Magnetic field -------------------------------------------------
TString fieldTag = "v18a";
Double_t fieldZ = 40.; // field centre z position
Double_t fieldScale = 0.; // field scaling factor
// ------------------------------------------------------------------------
// ----- Create setup ---------------------------------------------------
CbmSetup *setup = CbmSetup::Instance();
if (!setup->IsEmpty()) {
std::cout << "-W- setup_sis18_mcbm: overwriting existing setup"
<< setup->GetTitle() << std::endl;
setup->Clear();
}
setup->SetTitle("SIS18 - mCBM Setup");
setup->SetModule(ECbmModuleId::kPlatform, platGeoTag);
setup->SetModule(ECbmModuleId::kPipe, pipeGeoTag);
// setup->SetModule(ECbmModuleId::kMvd, mvdGeoTag); // skip mvd
setup->SetModule(ECbmModuleId::kSts, stsGeoTag);
setup->SetModule(ECbmModuleId::kMuch, muchGeoTag);
setup->SetModule(ECbmModuleId::kTrd, trdGeoTag);
setup->SetModule(ECbmModuleId::kTof, tofGeoTag);
setup->SetModule(ECbmModuleId::kRich, richGeoTag);
setup->SetModule(ECbmModuleId::kPsd, psdGeoTag);
setup->SetField(fieldTag, fieldScale, 0., 0., fieldZ);
// ------------------------------------------------------------------------
// ----- Screen output ------------------------------------------------
setup->Print();
// ------------------------------------------------------------------------
// clang-format on
}
#
## trd_v22a_mcbm information file
#
# created 20211028
# envelope
0.000000 cm start of TRD (z)
108.000000 cm end of TRD (z)
# thickness
27.000000 cm per single layer (z)
# extra gaps
0.000000 0.000000 0.000000 extra gaps in z (cm)
# generated TRD layers
1 2 3 planeID
# dimensions in x
-332.500000 cm to 332.500000 cm x-dimension of layer 1
-332.500000 cm to 332.500000 cm x-dimension of layer 2
-206.500000 cm to 206.500000 cm x-dimension of layer 3
# dimensions in y
-237.500000 cm to 237.500000 cm y-dimension of layer 1
-237.500000 cm to 237.500000 cm y-dimension of layer 2
-152.000000 cm to 152.000000 cm y-dimension of layer 3
# z-positions of layer front
0.000000 cm z-position of layer 1
27.000000 cm z-position of layer 2
81.000000 cm z-position of layer 3
# flags
support structure is : NOT included
radiator is : NOT included
lattice grid is : included
kapton window is : included
gas frame is : included
padplane is : included
backpanel is : included
Aluminium ledge is : included
Gibbet support is : included
Power bus bars are : NOT included
asics are : included
front-end boards are : included
GBTX readout boards are : included
# modules
mod1 mod2 mod3 mod4 mod5 mod6 mod7 mod8 mod9 mod10 total
---------------------------------------------------------------------------------
0 0 0 0 0 0 0 1 0 0 layer 1
0 0 0 0 0 0 0 1 0 0 layer 2
0 0 0 0 0 0 0 0 1 0 layer 3
---------------------------------------------------------------------------------
0 0 0 0 0 0 0 2 1 0 3 number of modules
# febs
9s 5s 6s 18 12 8 4 3 18 18 FEBs per module
0 ultimate FEBs
0s 0s 0s 0 super FEBs
0 0 0 6 6 regular FEBs
0 0 0 0 0 0 0 6 18 0 24 number of FEBs
# asics
10 10 10 10 8 8 8 8 10 10 ASICs per FEB
90 50 60 180 96 64 32 24 180 180 ASICs per module
0 0 0 0 0 0 0 48 180 0 228 number of ASICs
# gbtx
15 10 5 18 0 10 5 3 18 18 GBTXs per module
0 0 0 0 0 0 0 6 18 0 24 number of GBTXs
555 55 5 333333 0 55 5 3 333333 333333 GBTX ROB types on module
0 0 0 0 0 0 0 0 0 0 0 number of GBTX ROB7
0 0 0 0 0 0 0 0 0 0 0 number of GBTX ROB5
0 0 0 0 0 0 0 2 6 0 8 number of GBTX ROB3
# e-links
180 100 120 360 192 128 64 48 360 360 456 e-links used
210 140 70 252 0 140 70 42 252 252 336 e-links available
- - - - - - - 114.3% 142.9% - 135.7% e-link efficiency
# channels
1440 800 960 2880 3072 2048 1024 768 2880 2880 channels per module
160 160 160 160 256 256 256 256 160 160 channels per feb
0 0 0 0 0 0 0 1536 2880 0 4416 channels used
0s 0s 0s 0F 0 0 0 1536 2880F 0F 7296 channels available
39.5%u 0.0%s 21.1%r channel ratio
60.5% channel efficiency
2.71 m2 total surface
2.54 m2 total active area
0.03 m3 total gas volume
5.75 cm2/ch average channel size
1739.13 ch/m2 channels per m2 active area
# gas volume position
1.6000 cm position of gas volume - layer 1
28.6000 cm position of gas volume - layer 2
82.6000 cm position of gas volume - layer 3
# angles of acceptance
v: 89.46 deg, h: 89.62 deg - vertical/horizontal - layer 1
v: 82.99 deg, h: 84.98 deg - vertical/horizontal - layer 2
v: 61.30 deg, h: 68.05 deg - vertical/horizontal - layer 3
# inner aperture
v: 85.54 deg, h: 85.54 deg - vertical/horizontal - layer 1
v: 44.28 deg, h: 44.28 deg - vertical/horizontal - layer 2
v: 18.90 deg, h: 18.90 deg - vertical/horizontal - layer 3
#
## trd_v22b_mcbm information file
#
# created 20211028
# envelope
0.000000 cm start of TRD (z)
54.000000 cm end of TRD (z)
# thickness
27.000000 cm per single layer (z)
# extra gaps
0.000000 0.000000 extra gaps in z (cm)
# generated TRD layers
1 2 planeID
# dimensions in x
-332.500000 cm to 332.500000 cm x-dimension of layer 1
-332.500000 cm to 332.500000 cm x-dimension of layer 2
# dimensions in y
-237.500000 cm to 237.500000 cm y-dimension of layer 1
-237.500000 cm to 237.500000 cm y-dimension of layer 2
# z-positions of layer front
0.000000 cm z-position of layer 1
27.000000 cm z-position of layer 2
# flags
support structure is : NOT included
radiator is : NOT included
lattice grid is : included
kapton window is : included
gas frame is : included
padplane is : included
backpanel is : included
Aluminium ledge is : included
Gibbet support is : included
Power bus bars are : NOT included
asics are : included
front-end boards are : included
GBTX readout boards are : included
# modules
mod1 mod2 mod3 mod4 mod5 mod6 mod7 mod8 mod9 mod10 total
---------------------------------------------------------------------------------
0 0 0 0 0 0 0 1 0 0 layer 1
0 0 0 0 0 0 0 1 0 0 layer 2
---------------------------------------------------------------------------------
0 0 0 0 0 0 0 2 0 0 2 number of modules
# febs
9s 5s 6s 18 12 8 4 3 18 18 FEBs per module
0 ultimate FEBs
0s 0s 0s 0 super FEBs
0 0 0 6 6 regular FEBs
0 0 0 0 0 0 0 6 0 0 6 number of FEBs
# asics
10 10 10 10 8 8 8 8 10 10 ASICs per FEB
90 50 60 180 96 64 32 24 180 180 ASICs per module
0 0 0 0 0 0 0 48 0 0 48 number of ASICs
# gbtx
15 10 5 18 0 10 5 3 18 18 GBTXs per module
0 0 0 0 0 0 0 6 0 0 6 number of GBTXs
555 55 5 333333 0 55 5 3 333333 333333 GBTX ROB types on module
0 0 0 0 0 0 0 0 0 0 0 number of GBTX ROB7
0 0 0 0 0 0 0 0 0 0 0 number of GBTX ROB5
0 0 0 0 0 0 0 2 0 0 2 number of GBTX ROB3
# e-links
180 100 120 360 192 128 64 48 360 360 96 e-links used
210 140 70 252 0 140 70 42 252 252 84 e-links available
- - - - - - - 114.3% - - 114.3% e-link efficiency
# channels
1440 800 960 2880 3072 2048 1024 768 2880 2880 channels per module
160 160 160 160 256 256 256 256 160 160 channels per feb
0 0 0 0 0 0 0 1536 0 0 1536 channels used
0s 0s 0s 0F 0 0 0 1536 0F 0F 1536 channels available
0.0%u 0.0%s 100.0%r channel ratio
100.0% channel efficiency
1.80 m2 total surface
1.69 m2 total active area
0.02 m3 total gas volume
11.02 cm2/ch average channel size
907.37 ch/m2 channels per m2 active area
# gas volume position
1.6000 cm position of gas volume - layer 1
28.6000 cm position of gas volume - layer 2
# angles of acceptance
v: 89.46 deg, h: 89.62 deg - vertical/horizontal - layer 1
v: 82.99 deg, h: 84.98 deg - vertical/horizontal - layer 2
# inner aperture
v: 85.54 deg, h: 85.54 deg - vertical/horizontal - layer 1
v: 44.28 deg, h: 44.28 deg - vertical/horizontal - layer 2
Markdown is supported
0% or .
You are about to add 0 people to the discussion. Proceed with caution.
Finish editing this message first!
Please register or to comment