1. Outer Tracker Nominal Position
Antonio Pellegrino (on behalf of the LHCb OT Group)
CERN,
Introduction
C-Frames Nominal Positions
Reference Frames
Tables of Nominal Positions
Comparison with XML
Modifications to nominal values
Outlook

2. Global View
January 12, 2019
Antonio Pellegrino

3. In Reality…
January 12, 2019
Antonio Pellegrino

4. “A” Side “C” Side OT C-Frames Z X IP T3-Q02-VX T3-Q02-XU T2-Q02-VX
January 12, 2019
Antonio Pellegrino

5. Nominal Positions ZSurvey XSurvey 682 685 120 Rail Description
XSurvey (mm)
ZSurvey (mm)
T1-XU
T1 – Layers L0,L1 {X,U}
-7888
28.4
T1-VX
T1 – Layers L2,L3 {V,X}
-8008
28.8
T2-XU
T2 – Layers L0,L1 {X,U}
-8570
30.9
T2-VX
ST2 – Layers L2,L3 {V,X}
-8690
31.3
T3-XU
T3 – Layers L0,L1 {X,U}
-9255
33.3
T3-VX
T3 – Layers L2,L3 {V,X}
-9375
33.8
January 12, 2019
Antonio Pellegrino

6. Survey and LHCb Frame   3.601  10-3 rad January 12, 2019
Antonio Pellegrino

7. Nominal Positions ZSurvey XSurvey 682 685 120 Rail XSurvey (mm)
ZSurvey (mm)
ZLHCb (mm)
YLHCb (mm)
T1-XU
-7888
28.4
-0.005
T1-VX
-8008
28.8
-0.037
T2-XU
-8570
30.9
0.039
T2-VX
-8690
31.3
0.007
T3-XU
-9255
33.3
-0.027
T3-VX
-9375
33.8
0.040
Rounding of ZSurvey  YLHCb ≠ 0, C-Frames centers not exactly in YLHCb = 0
January 12, 2019
Antonio Pellegrino

8. 36  (Px,Py,Pz) survey points: mostly only 18 measured (1 Layer)2 3 4 5 6 7 8 9
dowel pins 1 2 3 4 5 6 7 8 9
2 Layers  9 Modules/Layer  2 dowel pins/Module (top/bottom)
36  (Px,Py,Pz) survey points: mostly only 18 measured (1 Layer)
January 12, 2019
Antonio Pellegrino

9. Stick survey target in here!
Targets
Stick survey target in here!
dowel pins
January 12, 2019
Antonio Pellegrino

10. Positions along the beam axis
T1-L1-Q2-M1 32 10 C
6.5
YSurvey
54.5 M
T1-L1-Q2-M1
6.5
XSurvey 15 T
January 12, 2019
Antonio Pellegrino

11. Nominal XSurvey T1-L0-Q0-M1 -7823.5 T1-L0-Q0-M2 T1-L0-Q0-M3
XSurvey (mm)
YSurvey (mm)
ZSurvey (mm)
T1-L0-Q0-M1
T1-L0-Q0-M2
T1-L0-Q0-M3
T1-L0-Q0-M4
T1-L0-Q0-M5
T1-L0-Q0-M6
T1-L0-Q0-M7
T1-L0-Q0-M8
T1-L0-Q0-M9
XSurvey (mm)
YSurvey (mm)
ZSurvey (mm)
T1-L1-Q0-M1
T1-L1-Q0-M2
T1-L1-Q0-M3
T1-L1-Q0-M4
T1-L1-Q0-M5
T1-L1-Q0-M6
T1-L1-Q0-M7
T1-L1-Q0-M8
T1-L1-Q0-M9
XSurvey (mm)
YSurvey (mm)
ZSurvey (mm)
T1-L0-Q2-M1
T1-L0-Q2-M2
T1-L0-Q2-M3
T1-L0-Q2-M4
T1-L0-Q2-M5
T1-L0-Q2-M6
T1-L0-Q2-M7
T1-L0-Q2-M8
T1-L0-Q2-M9
XSurvey (mm)
YSurvey (mm)
ZSurvey (mm)
T1-L1-Q2-M1
T1-L1-Q2-M2
T1-L1-Q2-M3
T1-L1-Q2-M4
T1-L1-Q2-M5
T1-L1-Q2-M6
T1-L1-Q2-M7
T1-L1-Q2-M8
T1-L1-Q2-M9
January 12, 2019
Antonio Pellegrino

12. Vertical Positions
4900
9.323
January 12, 2019
Antonio Pellegrino

13. “Special” OT Modules Z Z Y “F” module are one physical unit
+7mm Z
S1U
S2U
S3U
S1U
-7mm Z Y
S1L
S2L
S3L
S1L
“F” module are one physical unit
“S” modules are realized gluing together two separate parts (“U” and “L”) Y
January 12, 2019
Antonio Pellegrino

14. Vertical Positions S2 S3 Z Y +7mm -7mm January 12, 2019
Antonio Pellegrino

15. Nominal ZSurvey T1-L0-Q0-M1 -7823.5 -2421.6 T1-L0-Q0-M2 T1-L0-Q0-M3
XSurvey (mm)
YSurvey (mm)
ZSurvey (mm)
T1-L0-Q0-M1
T1-L0-Q0-M2
T1-L0-Q0-M3
T1-L0-Q0-M4
T1-L0-Q0-M5
T1-L0-Q0-M6
T1-L0-Q0-M7
T1-L0-Q0-M8
T1-L0-Q0-M9
XSurvey (mm)
YSurvey (mm)
ZSurvey (mm)
T1-L1-Q0-M1
T1-L1-Q0-M2
T1-L1-Q0-M3
T1-L1-Q0-M4
T1-L1-Q0-M5
T1-L1-Q0-M6
T1-L1-Q0-M7
T1-L1-Q0-M8
T1-L1-Q0-M9
XSurvey (mm)
YSurvey (mm)
ZSurvey (mm)
T1-L0-Q2-M1
2478.4
T1-L0-Q2-M2
T1-L0-Q2-M3
T1-L0-Q2-M4
T1-L0-Q2-M5
T1-L0-Q2-M6
T1-L0-Q2-M7
T1-L0-Q2-M8
T1-L0-Q2-M9
2471.4
XSurvey (mm)
YSurvey (mm)
ZSurvey (mm)
T1-L1-Q2-M1
2469.1
T1-L1-Q2-M2
T1-L1-Q2-M3
T1-L1-Q2-M4
T1-L1-Q2-M5
T1-L1-Q2-M6
T1-L1-Q2-M7
T1-L1-Q2-M8
T1-L1-Q2-M9
2462.1
January 12, 2019
Antonio Pellegrino

16. Distance from the Beam Line
129.67
170 86
258.23
341.25
341.25
257.25
341.25 Y= Y=
340
340
172
340
1.25
1.25
1.25
January 12, 2019
Antonio Pellegrino

17. Nominal YSurvey T1-L0-Q0-M1 -7823.5 2816.63 -2421.6 T1-L0-Q0-M2
XSurvey (mm)
YSurvey (mm)
ZSurvey (mm)
T1-L0-Q0-M1
T1-L0-Q0-M2
T1-L0-Q0-M3
T1-L0-Q0-M4
T1-L0-Q0-M5
T1-L0-Q0-M6
T1-L0-Q0-M7
769.13
T1-L0-Q0-M8
427.88
T1-L0-Q0-M9
170.63
XSurvey (mm)
YSurvey (mm)
ZSurvey (mm)
T1-L1-Q0-M1
T1-L1-Q0-M2
T1-L1-Q0-M3
T1-L1-Q0-M4
T1-L1-Q0-M5
T1-L1-Q0-M6
T1-L1-Q0-M7
985.27
T1-L1-Q0-M8
642.72
T1-L1-Q0-M9
383.88
XSurvey (mm)
YSurvey (mm)
ZSurvey (mm)
T1-L0-Q2-M1
2478.4
T1-L0-Q2-M2
T1-L0-Q2-M3
T1-L0-Q2-M4
T1-L0-Q2-M5
T1-L0-Q2-M6
T1-L0-Q2-M7
769.13
T1-L0-Q2-M8
427.88
T1-L0-Q2-M9
170.63
2471.4
XSurvey (mm)
YSurvey (mm)
ZSurvey (mm)
T1-L1-Q2-M1
2469.1
T1-L1-Q2-M2
T1-L1-Q2-M3
T1-L1-Q2-M4
T1-L1-Q2-M5
T1-L1-Q2-M6
900.76
T1-L1-Q2-M7
558.21
T1-L1-Q2-M8
215.66
T1-L1-Q2-M9
-41.96
2462.1
January 12, 2019
Antonio Pellegrino

18. Tables of Nominals
All nominal values of the survey targets (dowel pins) coordinates can be found in the tables in
OT Web Page
Installation
Survey
Overview of Raw Data
January 12, 2019
Antonio Pellegrino

19. Comparison to XML (XSurvey and YSurvey)
Nominal values in the XML description of the OT Geometry (provided by Jan Amoraal):
One nominal value taken at each module centre
  (Antonio’s table) – (Jan’s XML)
XSurvey
YSurvey
Comparison shows identical values (differences ~10 m from rounding)
January 12, 2019
Antonio Pellegrino

20. Comparison to XML (ZSurvey)
Rail
XSurvey (mm)
ZSurvey (mm)
ZLHCb (mm)
YLHCb (mm)
T1-XU
-7888
28.4
-0.005
T1-VX
-8008
28.8
-0.037
T2-XU
-8570
30.9
0.039
T2-VX
-8690
31.3
0.007
T3-XU
-9255
33.3
-0.027
T3-VX
-9375
33.8
0.040
Rounding of ZSurvey  YLHCb ≠ 0, C-Frames centers not exactly in YLHCb = 0
January 12, 2019
Antonio Pellegrino

21. Adjustments
What knobs can you turn if the survey turns out to be crap?
Displace hook block wrt to frame modifies XLHCb
Displace roller block wrt to frame modifies ZLHCb
Adjust spacer under trolley modifies YLHCb
January 12, 2019
Antonio Pellegrino

22. Modifications to Nominal Values
During the OT installation, various iterations of surveys and adjustments were carried out
All 18 dowel pins of one of the two layers of a C-Frame were surveyed
typically L0 (X) and L2 (V)
(for one C-Frame, both layers were surveyed, as a check)
Comparing the surveyed values to the nominal tables, adjustments were made
When the adjustment range was not sufficient to achieve the nominal values, the priority was given to limiting rotations
avoiding rotations around XLHCb and YLHCb sometime implied modifying the nominal ZLHCb of a half-station (both sides A and C)
a slight deformation in the shape of all C-Frames effectively caused an effect of rotation around ZLHCb. This could be eliminated to the cost of a systematical modification (“staggering”) of the YLHCb of all modules.
These modifications to the nominal values have not been reported on the OT Web Page, but only through “private communications” (Jan and Marc)
January 12, 2019
Antonio Pellegrino

23. Modifications to Nominal XSurvey
Limiting rotations around XLHCb and YLHCb sometime implied modifying the nominal ZLHCb of a half-station (both sides A and C)
Half Station
XSurvey (mm)
XSurvey (mm)
T1-XU
-7888
0.0
T1-VX
-8008
0.5
T2-XU
-8570
2.5
T2-VX
-8690
3.5
T3-XU
-9255
T3-VX
-9375
January 12, 2019
Antonio Pellegrino

24. Modifications to Nominal YSurvey
A slight deformation in the shape of all C-Frames effectively caused an effect of rotation around ZLHCb. This could be eliminated to the cost of a systematical modification (“staggering”) of the YLHCb of all modules
Expected
Instead was
Compromise  Z
  0.46  10-3 rad Y
January 12, 2019
Antonio Pellegrino

25. Summary and Outlook
OT C-Frames were adjusted with respect to survey targets nominal positions
typically surveyed one layer per C-Frame (L0 (X) and L2 (V))
Systematic comparison with center modules nominal positions in OT Geometry XML
comparison ok
differences in ZSurvey due to rounding, easy to correct
comparison of dowel pin positions under way
deviations of “special” modules in T1 and T3 not yet implemented
Modifications to nominal positions were done to limit rotations
nominal ZLHCb of a half-station (both sides A and C)
systematical modification (“staggering”) of the YLHCb of all modules
what is the right place to “book-keep” these modifications??
January 12, 2019
Antonio Pellegrino

26. Jan’s Transformation in XML
ZCLHCb
January 12, 2019
Antonio Pellegrino