Infrastructure for LHCb Upgrade workshop – MUON detector Infrastructure for LHCB Upgrade workshop: MUON power, electronics, cable Muon upgrade in a nutshell.

Slides:

Advertisements

Similar presentations

M.PEGORARO Grounding Workshop 24th Jan 08 DT GROUNDING & SHIELDING Presented by A. BENVENUTI.

Advertisements

Bagby L0 Workshop L0 Infrastructure  Mapping  Installations u Horseshoe Area s Adapter Card u Cathedral s Low Voltage Fuse Panel u Platform s.

LECC V. Bobillier1 Overview of LHCb Electronics installation aspects V. Bobillier; L. Roy; J. Christiansen CERN - LHCb.

04/02/2004 az Outer Tracker Distribution Boxes 1 EFNI H K Outer Tracker Distribution Boxes Ad Berkien Tom Sluijk Albert Zwart.

Walls crates cables gas chambers electronics CERN adb.

Power supply planning for upgrade OT  Scintillating Fibre Wilco Vink On behalf of the SciFi group 19 May 2014.

Niko Neufeld CERN PH/LBC. Detector front-end electronics Eventbuilder network Eventbuilder PCs (software LLT) Eventfilter Farm up to 4000 servers Eventfilter.

Experimental Area Meeting V. Bobillier1 Good connection to earth (in many points) of every metallic parts to be installed in the cavern is very.

A* candidate for the power supply Wiener MPOD-LV crate w/ remote control only (except for local on/off switch) Type “EC LV” Front or rear connections (reverse.

The High Voltage, Monitoring and Control systems of the Hadronic and Electromagnetic calorimeters are essentially slow control based, and therefore are.

ECS for Front-End crates MARATON. 2 Introduction Front-End crates are powered by MARATON power supplies, located on the platform, at the back of each.

Calorimeter upgrade meeting - Wednesday, 11 December 2013 LHCb Calorimeter Upgrade : CROC board architecture overview ECAL-HCAL font-end crate  Short.

VELO upgrade Front-end ECS LHCb upgrade electronics meeting 12 April 2012 Martin van Beuzekom on behalf of the VELO upgrade group Some thoughts, nothing.

Saverio Minutoli INFN Genova 1 1 T1 Electronic status Electronics Cards involved: Anode Front End Card Cathode Front End Card Read-Out Control card VFAT.

LKr Calorimeter Control and monitoring R. Fantechi 19/02/2010 R. Fantechi.

V. Bobillier1 Long distance cable installation status Calorimeter commissioning meeting.

1 5 December 2012 Laurent Roy Infrastructure / Electronics Upgrade -Cabling (long distance) -Rack and Crate (space, electrical distribution, cooling) -Detector.

ALICE DCS Workshop 28/29 May 2001 Vito Manzari, INFN Bari SSD (Silicon Strip Detector) SDD (Silicon Drift Detector) SPD (Silicon Pixel Detector) Detector.

XXVI Workshop on Recent Developments in High Energy Physics and Cosmology Theodoros Argyropoulos NTUA DCS group Ancient Olympia 2008 ATLAS Cathode Strip.

Problems with Muon System N. Bondar O.Maev

Goals: - To get experience in assembling MWPC on the Wall and prevent possible problems; - To check functionality and stability of different chambers at.

ECS for Front-End crates MARATON. 2 Introduction Front-End crates are powered by MARATON power supplies, located on the platform, at the back of each.

Muon Electronics Upgrade Present architecture Remarks Present scenario Alternative scenario 1 The Muon Group.

1 Status and Outlook of the RPC Commissioning Marcello Maggi/INFN-Bari.

Service box / Patch panel Cabling detector counting room Power supplies LV and HV LHCb Outer Tracker Services and Infrastructure.

L0 Technical Readiness Review-Electronics Installation Linda Bagby L0 Electronics Installation  System Electronics Overview u Low Voltage s Filter.

Update on CHANTI F. Ambrosino, T. Capussela, D. Di Filippo, P. Massarotti, M. Napolitano, L. Roscilli, G. Saracino Università degli Studi di Napoli «Federico.

cm 150 cm The Al foil is large as the M3 wall  we can put 1 raw (5 chambers) or 2 raws There is an insulating material (varnish) on the.

Director’s Review of RunIIb Dzero Upgrade Installation Linda Bagby L0 Electronics Installation  System Electronics Overview u Low Voltage u High.

Muon Piquet Training V.0 W Baldini, E.Furfaro, O. Maev June 11-th 2015.

9/18/2003Safety Review Electronics Electronics design LV, HV power supply Fusing Heat.

Preparation of chamber training g. passaleva. Gaps to be trained We have O (100) gaps that have tripped at least once since June At a quick glance they.

9/17/2008TWEPP 2008, R. Stringer - UC Riverside 1 CMS Tracker Services: present status and potential for upgrade Robert Stringer University of California,

13-Mar-061 ACORDE DCS ACORDE GROUP CINVESTAV, ICN-UNAM, MICHOACAN. PUEBLA México.

Infrastructure for LHCb Upgrade workshop – MUON detector Infrastructure for LHCB Upgrade workshop: MUON power, electronics Muon upgrade in a nutshell LV.

Could we abandon the HW LLT option and save money (and allow possible further improvements to the upgraded muon system)? Alessandro Cardini of behalf of.

PHENIX Safety Review Overview of the PHENIX Hadron Blind Detector Craig Woody BNL September 15, 2005.

IB PRR PRR – IB System.

SPD VFE installation and commissioning (status and plans) I.Summary of VFE installation II.Stand alone VFE test: noise & offset III.Stand alone test: LED.

Saverio MINUTOLITOTEM Electronics W.G., 9 December T1 electronics status.

Muon System Update: Next Steps Alessandro Cardini INFN Cagliari.

HV-system Oleg Maev 1. Brief overview of HV-systems Muon chambers circuits 2. States of HV according LHC/LHCb conditions 3. Useful practical applications/knowleges/tools.

Summary of FEE-Integration Meeting LNF, Summary of the Frascati meeting on chamber & front-end integration on 10 September 2003, provided.

CERN – 7 Oct 04 1 LHCb Muon Grounding Anatoli Katchouk CERN Alessandro Balla, Paolo Ciambrone, Maurizio Carletti, Giovanni Corradi, Giulietto Felici, Rosario.

TOF status and LS1 plansTOF status and LS1 plans 27/06/2012.

DCS workshop,march 10th P.Saturnini, F. Jouve Slow control trigger of the muon arm Muon trigger of the muon arm Low voltage VME Crate External parameters.

E Ethernet C CAN bus P Profibus HV HV cables LV LV cables (+busbar) S Serial (RS232) Signal cable Other/Unknown Liquid or Gas Cable and/or Bus PCI-XYZ.

1 DCS Meeting, CERN (vydio), Jun 25th 2013, A. Cotta Ramusino for INFN and Dip. Fisica FE Preliminary DCS technical specifications (v1.0) for the Gigatracker.

1 Chamber Interfaces Adalberto Readout-, I2C-, HV-, LV-, Gas- and chamber support interface. Space issues.

Faculty of Physics, University of Belgrade Collaboration meeting, Budapest 15 th of May, ToF-L/R detector HV upgrade Jovan Puzović, Faculty of Physics,

Faculty of Physics, University of Belgrade Collaboration board meeting 31 th of January, ToF-L/R detector HV upgrade Jovan Puzović, Faculty of Physics,

Martin van Beuzekom, Jan Buytaert, Lars Eklund Opto & Power Board (OPB) Summary of the functionality of the opto & power board.

Current STS Readout Concept 1 FEB 8 STS-XYTER Electrical Interface SLVS/LVDS pairs/FEB ROB GBTx / VL Optical Interface 4 MM fibers /ROB DPB.

LHCb Outer Tracker Electronics 40MHz Upgrade

Cabling for LHCb Upgrade

LKr status R. Fantechi.

Upgrade activities at Clermont-Ferrand

General aspects: Optical links :

UT Optical Connections

T1 Electronic status Conclusions Electronics Cards:

PMT cabling Gian Luca Raselli INFN Pavia

ALICE Muon Tracking Upgrade EDR Answers

Electronics for RPC Upscope

Fiber Installation for RUN 3&4

LHCb Outer Tracker Upgrade Developments

To do list production organization and commitments

Pierluigi Paolucci - I.N.F.N. Naples

RPC HV&LV status Introduction HV power supply tender

Overview of T1 detector T1 is composed by 2 arms

Pierluigi Paolucci & Giovanni Polese

Presentation transcript:

Infrastructure for LHCb Upgrade workshop – MUON detector Infrastructure for LHCB Upgrade workshop: MUON power, electronics, cable Muon upgrade in a nutshell LV power scheme HV power scheme Optical fibers connections Conclusions Paolo Ciambrone Alessandro Cardini for the muon group

Infrastructure for LHCb Upgrade workshop – MUON detector Remove M1 station Preserve the present MWPCs and their front-end electronics in M2-M5 stations –to improve the detector performances at high luminosity, the replacement of the innermost chambers of M2 and M3 with high granularity detectors is under study Maintain the present Intermediate Board (IB) system (with the exception of M5R4) to generate the logical channels Use new Off Detector Electronics (nODE) boards for an efficient 40 MHz –Back compatible with the current off detector electronics and crates –Based on new custom ASIC (nSYNC), GBT and versatile link components Replace the Service Board (SB) system –Efficient chamber pulsing (nPDM) and control (nSB) via GBT and versatile link components Muon upgrade in a nutshell 2 19/02/2015

Infrastructure for LHCb Upgrade workshop – MUON detector Based on Maraton System –Primary rectifiers and Remote Controllers in a safe environment (behind the wall) –Long cables + patch panels (in a fixed position) + movable cable chain –Maraton Power boxes on each rack of the muon towers Front-end electronics (FEE) powering scheme –Maraton power box + patch panel (rack) + linear regulator (on detector) Each FEE power box has V/55A (330 W maximum) –8 FEE power boxes installed (2 for M1, 4 for M2-M3, 2 for M4-M5) Present maximum power consumption per power box ~ 1kW Present maximum power (current) consumption per channel –~ 172 W (43A) in M4-M5 –~ 130 W (34A) in M2-M3 Current LV power scheme 3 19/02/2015

Infrastructure for LHCb Upgrade workshop – MUON detector Off detector electronics powering scheme –1 Maraton power box per rack Up to 4 crates (IB, ODE, SB) per power box Each power box has –2 2..7V/110A (660 W) –8 2..7V/55 A (330 W) –10 off detector electronics power boxes installed (2 for M1, 4 for M2-M3, 4 for M4-M5) Present maximum power consumption per power box ~ 500 W Current LV power scheme 4 19/02/2015

Infrastructure for LHCb Upgrade workshop – MUON detector Upgraded power system will use the current Maraton System components and cables –M1 will be removed All system components can be used as spares –M2-M5 FEE power boxes No changes foreseen –6 FEE power boxes + 6 patch panels required (in the racks of the muon towers -UXB) –Enough margin to handle a potential power increase with the rate In case of innermost M2-M3 chambers replacement 2 more power boxes should be foreseen –M2-M5 off detector electronics power boxes No changes foreseen –8 power boxes required (in the racks of the muon towers- UXB) –The new nODE, nSB and nPDM boards will use the current rack power lines and they will generate internally the new required voltages –Current power is enough »A local (rack level) power line reshuffling for the high power channels could be needed –14 (+2) AD/DC primary rectifiers in 4 power boxes (in the rack behind the wall – UXA-B) No changes foreseen –14 RCM (+2) controller modules in 2 VME like crates (in the rack behind the wall – UXA-B) No changes foreseen –Current cabling can be maintained In case of innermost M2-M3 chambers replacement 2 more power and control cables should be installed Upgraded LV power scheme 5 19/02/2015

Infrastructure for LHCb Upgrade workshop – MUON detector Upgraded LV power distribution diagram Upgraded LV power scheme 12 x 3,8V 1x55 3x55 4x55 AC/DC Control 6 19/02/2015

Infrastructure for LHCb Upgrade workshop – MUON detector No changes are foreseen in the high voltage systems and cabling (just remove the M1 components) –CAEN EASY 3000 In a safe environment –2 SY1527LC Mainframe –2 A1676 branch controllers –2 A V Power supplies + 2 additional (custom) 48V for EASY3000 logic supply –1 Local patch panel On detector –2 cavern patch panels + cable chain –4 EASY3000 crates –18 A3535 HV modules Upgraded HV power scheme 7 19/02/2015

Infrastructure for LHCb Upgrade workshop – MUON detector SY1527 Mainframe A 1676 controllers Detailed CAEN EASY 3000 HV power system diagram Upgraded HV power scheme 48V PS & service for M1-M5 (side A) Ch. 2 Ch. 1 48V PS & service for M1-M5 (side C) M1 (side A) EASY 3000 crates PP (side C) SY1527 Mainframe A 1676 controllers M2-M5 (side A) EASY 3000 crates M2-M5 (side C) EASY 3000 crates M1 (side C) EASY 3000 crates PP (side A) Ch. 2 Ch. 1 Local PP Wall M1 PP (side A) M1 PP (side C) Control cable Power cable Control patch cable Sense cableSpare cable Power patch cable 8 19/02/2015

Infrastructure for LHCb Upgrade workshop – MUON detector PNPI HV system for M2-M5 station –In a safe environment 2 primary HV power supplies (Matsusada) 2 master crates 16 master boards (in D3) (8 channels each) 1 LV power supply Box with 4 credit card PCs (2 in use right now) Control with USB interface 1 HVM Control Unit (10 hosts, 5 per side) 1 Master HV patch panel 1 Master LV patch panel 1 Master control patch panel –On detector 2 cavern patch panels + cable chain 16 distributor crates 112 distributor boards (for a total of 4032 HV channels, supplying each of the 4 sensitive gaps on 960 M2-M5 R3+R4 chambers) (192 spare channels) Upgraded HV power scheme 9 19/02/2015

Infrastructure for LHCb Upgrade workshop – MUON detector Detailed PNPI HV system diagram Upgraded HV power scheme 10 19/02/2015 CCPC box + USB interface

Infrastructure for LHCb Upgrade workshop – MUON detector (M1 + M2-M5) ODE boards –12 parallel optical fibers for L0trigger per board  ribbon cables MPO-MPO in total –1 DAQ single fiber per board  ribbon cables MPO-MPO in total –1 TFC single fiber per board PDM –1 TFC single fiber per board optical patch panels in the racks + cable chain + 2 cavern patch panels Current optical fibers connections ODE transmitters Rack P.P. MPO-MPO Cavern P.P. MPO-MPO Wall Barrack MPO-SC Cassette Multi- ribbons cables L0 muon Processing Board ribbon cables Rack P.P. SC-MPO Barrack P.P. MPO-MPO TELL1 board Cable chain 11 19/02/2015

Infrastructure for LHCb Upgrade workshop – MUON detector 108 (148 in case of M2-M3 inner chambers replacement) nODE boards –4 DAQ simplex links per board  432 (592) simplex links in total –1 TFC duplex links per board  108 (148) duplex links in total 8 PDM PDM –1 TFC/ECS duplex links per board  8 duplex links in total 8 optical patch panels in the racks + cable chain + 2 cavern patch panel –Use LC-to-MPO adapter in the rack patch panels –Try to re-use the present ribbon cables (to be tested) DAQ  36 (50) ribbon cables required TFC/ECS  20 (28) ribbon cables required New multi-ribbon cables required Upgraded optical fibers connections nODE Rack P.P. MPO-MPO Cavern P.P. MPO-MPO Wall ~300m Multi- ribbons cables ribbon cables Barrack P.P. MPO-MPO (at surface) Cable chain nSYNC VTTx GBTx VTTx VTRx GBT SCA nSYNC GBTx 12 19/02/2015

Infrastructure for LHCb Upgrade workshop – MUON detector No change required in crates and racks on the muon towers No major change foresees for LV power system –Re-use present Maraton components for frond-end electronics and off detector electronics power supply –Existing electrical power seems enough –Present cabling could be maintained –2 new power boxes and cables should be installed in case of innermost M2-M3 chambers replacement No change foresees for HV power system New multi-ribbons cables required for DAQ and TFC/ECS links –Try to re-use single ribbon cables from rack patch panels to cavern patch panels Conclusions 13 19/02/2015