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Jorgen Christiansen, CERN PH-ESE 1.  6x Pixel channels: 130M pixels -> 800M pixels ◦ Smaller pixels. 100x150um 2 -> Inner: 25x100um 2 /50x50um 2, Outer:

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Presentation on theme: "Jorgen Christiansen, CERN PH-ESE 1.  6x Pixel channels: 130M pixels -> 800M pixels ◦ Smaller pixels. 100x150um 2 -> Inner: 25x100um 2 /50x50um 2, Outer:"— Presentation transcript:

1 Jorgen Christiansen, CERN PH-ESE 1

2  6x Pixel channels: 130M pixels -> 800M pixels ◦ Smaller pixels. 100x150um 2 -> Inner: 25x100um 2 /50x50um 2, Outer: 100x100um 2 ◦ Larger detector: 2m 2 -> 4m 2  10x Hit rates: 200MHz/cm 2 -> 2-3GHz/cm 2 inner layer  4(6)x Trigger latency: 3.2us -> 12us (20us) ◦ ~40x larger latency data buffers (zero-suppressed)  10x Trigger rates: 100KHz -> ~1MHz ◦ ~100 x readout data rate: ~4GBits/s per chip in inner layer  10x radiation levels ◦ Increased leakage, etc. ◦ High SEU rates require extensive fault tolerance  65nm low power technology using ~1V power supply: ◦ Low power, Low voltage but high currents  Major Implications for power distribution !. ◦ 1-4x power density compared to current pixel detectors depending on location and assumed scenario. ◦ Even for same power density, currents gets higher because of lower power supply voltage for 65nm pixel chips.  5-10x higher currents -> 25-100x cable losses 2

3 3 Phase 1 pixel, PU140 100x150x300um 3 Phase 2 pixel, PU200, 25x100x150 μm 3 E. Migliore, Torino CMS phase 2 tracker layout CMS phase 1 pixel services 3GHz/cm 2 1/4 Occupancy 2GHz/cm 2

4  Pixel modules: ◦ L1: ~10MGy (1Grad), ~10 16 Neu/cm 2 ◦ L2: ¼, L3: 1/8, L4: 1/16, ID: 1/5, OD: 1/10  Services (r= ~16cm): ~100Mrad, ~10 15 Neu/cm 2 ◦ No reduction going further down in Z ◦ Difficult to go further out in r (outer tracker, replacability of pixel) 4

5 5 To be confirmed if 4x2 pixel modules can be built (bump-bonding)

6  Minimal mass of local power cabling  Modular approach with independent services per pixel module (if possible). ◦ Stave concept if required (e.g. serial powering) ◦ Failure propagation to be well understood if not independent services  Replace pixel detector (or parts of it) in “yearly/long shut down”. ◦ Radiation damage or other problems ◦ Special mechanics and related connectors for power/readout services  Long distance power cabling and related power losses ◦ Can existing power cables be used ? (no)  Power cabling cooling ?  Powering of opto services: ◦ ~500 10Gbits/s LPGBTs on service cylinders ( 5Tbits/s !) ◦ ~1kW  Off-detector power supplies ◦ Radiation tolerance (in cavern), ◦ Availability, ◦ Cost, etc.  HV  Grounding.  Safety/protection system 6

7 L1L2L3L4IDODTotal r (mm)306810216045 - 8585-160 Pixel size (um 2 )50x50 100x10050x50100x100 Track rate: (relative)500MHz/cm 2 1/41/81/161/51/10 Hit rate: PU140: (PU200) 2GHz/cm 2 (3GHz/cm 2 ) 1/41/81/161/51/10 Facets: Per ladder: 12 8 14 8 22 8 32 81426 Module size chips: mm: 1 x 4 20x80 2 x 4 40x80 2 x 2 40x40 2 x 4 40x80 Disks 2 x 72 x 10 Modules961121762561965201356 Chips3848961408204878441609680 Hits per chip per Bx2005025134020 Event size per chip (bits)486812646643641024544 Event size (KBytes)2281381149198276946 Data rate per chip @ 500KHz trg. Gbits/s 2.430.630.330.180.510.27 Data rate per module Gbits/s9.735.062.661.462.052.18 E-links per module @1.2Gbs/s 8 (16)4 (8)2 (4) E-links @ 1.2Gbs/s 768 (1536) 448 (896) 352 (704) 512 (1024) 392 (784) 1040 (2080) 3512 (7024) 7 Baseline: PU: 140, Trg: 500KHz Option: PU: 200, Trg: 750KHz (2x readout)

8  High rate regions with 50x50um 2 pixels: Barrel L1  Medium rate regions with 50x50um 2 pixels: Barrel L2, L3, Inner disks  Low rate regions with 100x100um 2 pixels: Barrel L4, Outer disks 8 Pixel chip power: 2cm x 2cmConservativeOptimistic Analog power supply1.2v Pixel analog current (50x50um 2 )6uA per pixel4uA per pixel Pixel analog current (100x100um 2 )10uA per pixel6uA per pixel Digital power supply0.8 (1.0) v Digital power density, low rate0.2W/cm 2 0.1W/cm 2 Digital power density, medium rate0.25W/cm 2 0.12W/cm 2 Digital power density, high rate0.5W/cm 2 0.25W/cm 2 High rate pixel chip (50x50): Analog (1.2v) current per chip0.96A0.64A Digital (0.8v) current per chip2.50A1.25A Total chip power (high rate 50x50)3.15W1.77W Medium rate pixel chip (50x50): Analog (1.2v) current per chip0.96A0.64A Digital (0.8v) current per chip1.25A0.60A Total chip power (med rate 50x50)2.15W1.25W Low rate pixel chip (100x100): Analog (1.2v) current per chip0.40A0.24A Digital (0.8v) current per chip1.00A0.50A Total chip power (low rate 100x100)1.28W0.69W Chip power density: Conservative: 0.3 – 0.8 W/cm 2 Optimistic: 0.2 – 0.4 W/cm 2 (Current pixel: 0.2 -0.3 W/cm 2 )

9 9 Pixel module powerConservativeOptimistic L1 pixel module power (50x50um2, 4 chips)12.6W7.0W L2 pixel module power (50x50um2, 8 chips)17.2W9.9W L3 pixel module power (50x50um2, 8 chips)17.2W9.9W L4 pixel module power (100x100um2, 8 chips)10.2W5.5W ID pixel module power (50x50um2, 4 chips)8.6W5.0W OD pixel module power (100x100um2, 8 chips)10.2W5.5W Pixel power overviewConservativeOptimistic Fraction power (%) Fraction chips (%) L1 (96 modules)1210W678W7.74.0 L2 (112 modules)1928W1118W12.29.3 L3 (176 modules)3030W1757W19.214.5 L4 (256 modules)2621W1409W16.621.2 ID (196 modules)1687W978W10.78.1 OD (520 modules)5324W2862W33.743.0 Total15801W8803W100.0 Module power: Conservative: 9 – 17W Optimistic: 5 – 10W (Module current = ~Module power) Total power: Conservative: 16kW Optimistic: 9kW (Total current= ~9-16KA)

10  Direct from external PS: Excluded ◦ Huge power cables and huge power losses in cables ◦ Ω=V drop /I = L/A * σ, Mass=L*A*ρ, Total voltage drop=2*V drop ◦ Mass=L 2 * I * σ * ρ / V drop per wire (2 wires required) ◦ Alu: σ= 2.82×10 −8 Ω*m, ρ=2700kg/m 3 ◦ Local power cabling within acceptance: 1-2m (in practice more)  L=1m, V drop =0.2V, I=16kA => Mass= 12kg  L=2m, V drop =0.2V, I=16kA => Mass= 48kg ( L 2 dependency) ◦ Global power cabling: 50m  L=50m, V drop =1V (problematic !), I=16kA => Mass= 6100kg, 2/3 power lost in cables  One-stage on-chip/on-module DC/DC: Not attractive for low conversion factors ◦ On-chip power conversion ratio will be limited by technology and radiation: 2-4  Local 1m: 12kg/ 2-4 = 3-6kg  Local 2m: 48kg / 2-4 = 12-24kg  Global 50m: 6100kg/ 2-4 = 1500 – 3000kg ◦ If on-chip/on-module power conversion factor of 6-10 can be envisaged then this can be attractive  One-stage remote DC/DC: Excluded ◦ Local power cables mass will be the same as “direct from external”.  Local 1-2m power cabling: 12-48kg  Global power cabling: 6100kg / ~10 = 610kg  Two stage DC/DC (remote + on-chip): More detailed study  Serial powering: More detailed study ◦ Cable mass reduced proportional to number of units put in series ( e.g. 8) ◦ Within pixel module or Across multiple pixel modules  Combination of serial and DC/DC: Exotic combination not yet considered ◦ Local serial powering from “remote” DC/DC converter with current output ◦ Global serial powering with on-chip DC/DC ◦ Complicated and no significant gain. 10

11 11 On-chip DC/DC: Switched capacitor Analog: Factor 2 + 0.1 V LDO Digital: Factor 3 Higher conversion factor (4-8) would be very advantageous but seems unrealistic On-chip capacitors ? “FEAST3” Voltage drop/ Distance 0.1v, 9kW 0.1v, 16kW 0.2v, 9kW 0.2v, 16kw 0.4v, 9kW 0.4v, 16kW 0.5m1.5 kg2.7 kg0.75 kg1.3 kg0.37 kg0.67 kg 1.0m6.0 kg11 kg3.0 kg5.3 kg1.5 kg2.7 kg 2.0m24.0 kg43 kg12 kg21 kg6.0 kg11 kg Voltage dropOpt: 9kWCon: 16kW 0.1v780 W1400 W 0.2v1570 W2800 W 0.4v3140 W5600 W Local power cable losses Module current at 2.6V: Conservative: 4-8A Optimistic: 2-5A (On-chip DC/DC: 90% efficiency) Local power cabling mass Dedicated cable cooling required ? On-chip DC/DC: Reduce mass of local power cabling Remote DC/DC: Reduce mass of long distance power cabling Resolve over-voltage problems with dynamic load variations

12  Integration of remote DC/DC on service cylinder critical/difficult ◦ Remote DC/DC as close to pixel modules as possible (move opto conversion further out) ◦ Connectors for pixel detector insertion ? ◦ Cooling, mechanics, etc. ◦ Part of forward coverage 12 ~1g for 4A converter: Conservative: 2.8kg Optimistic: 1.4kg

13 Critical points:  Remote DC/DC distance: <1m ◦ Place for remote DC/DC + cooling on service cylinder  1Grad on-chip DC/DC realistic ? ◦ Nobody working actively on this ! ◦ On-chip capacitors ? ◦ Higher on-chip power conversion factor ?  Remote DC/DC ◦ Rad. Tol.: ~100Mrad, ~10 15 neu/cm 2 ◦ Current rating: 4-5A (or 8A) ◦ Can they be put in parallel ?. ◦ 1g mass realistic ? ◦ Synergy/same as for CMS OT ?.  Cable cooling ?  Overvoltage protection ◦ Dynamic changes ◦ Low power state  Material in forward region within phase 2 coverage !. ◦ 8(4)kg (cables + remote DC/DC) ◦ Other material 13 Two stage DC/DC overview Cons: 16kW Opt: 9kW Unit Analog pixel chip voltage1.2V Digital pixel chip voltage0.8V Intermediate DC/DC voltage2.6V Local power converter efficiency0.9 local analog DC/DC conversion ratio2 Analog LDO voltage drop0.1V Local digital DC/DC conversion ratio3 Total pixel chip power158028804W Power loss in local converters24021391W Total power to local converters1820410194W Local power routing distance1.00m Max voltage drop on power wire0.20V Power loss in cables28011568W Power delivered by remote DC/DC2100511763W Minimum module current (ID)3.842.24A Minimum power wire diameter (ID)0.830.63mm Max module current (L2, L3)7.694.49A Max power wire diameter (L2,L3)1.170.90mm Number of power cables (with 2 wires)1356 Total power cable mass (Alu)5.332.99kg Remote DC/DC mass2.81.4kg Effective local cable reduction: 12kg/5.3kg= 2.2 If including remote DC/DC mass this is reduced to 12kg/8kg =1.5 (determined by on-chip DC/DC conversion factor)

14  Inject current and “develop/regulate” required voltage with local shunt regulator ◦ Ensure to always inject enough current: ~10% more than max required ◦ If chip burns less power during a time period this power will be burned by local shunt -> Constant current -> Constant voltage -> Constant power  Slow external control loop (software) to adjust injected current according to consumption A. Between chips on same module ◦ Good: No power chaining between modules (failure propagation) ◦ Bad: Chips on same module at different potentials: comm., sensor interface (DC coupled) “Power conversion gain” limited by number of chips on module: 4 or 8 B. Between modules ◦ Put local shunts in parallel. Requires specific Shunt-LDO that enables this. ◦ Good: All chips on same module at same potential “Power conversion gain” can be increased by having many modules in power chain Current from failing shunt can be taken by 3(7) other shunts on module ◦ Bad:Failure propagation across modules in power chain Has been evaluated/tested by ATLAS pixel with FEI chips. Favours a chain/stave structure with option to short circuit failing modules 14 N: chips on module M: modules in chain

15  On-chip Shunt - LDO ◦ Flexible design to allow:  Multiple chips in parallel  Multiple Shunt-LDOs per chip to generate multiple voltages (e.g. 1.2V, 0.8V) ◦ Higher power loss (but still very attractive)  On-chip shunt - DC/DC ◦ Too complicated 15

16 16 Across-module Serial power overview Con: 16kW Opt: 9kW unit Local Shunt voltage1.3V Analog pixel chip voltage1.2V Digital pixel chip voltage0.8V Total active pixel chip power153928584W Analog LDO voltage drop0.1V Digital LDO voltage drop0.5V Total Power loss in LDO's59233002W Excessive current fraction0.10 Total excessive current power21321159W Total power to modules2344712744W Local power routing distance1.00m Max voltage drop on power wire0.20V Total power loss in 1m cables915498W Total power delivered2436213242W Power loops168 Total loops current (all)22891244A Average loop current13.627.41A Minimum loop current (Inner disk)9.725.46A Minimum wire diameter1.320.99mm Maximum loop current (L2, L3)19.4510.91A Maximum wire diameter1.871.40mm Loop voltage (typical)10.80 V Local power cable weight (Alu)1.740.95kg Modules in series: Barrel: 8 (stave) ID: 7 ( ½ rings) OD: 8 (1/3 rings) Effective local cable reduction: 12kg/1.74kg= 6.9 (determined by number of modules in series)

17 In-module Serial power overview Con: 16kW Opt: 9kW Unit Local Shunt voltage1.3V Analog pixel chip voltage1.2V Digital pixel chip voltage0.8V Total active pixel chip power158028804W Analog LDO voltage drop0.1V Digital LDO voltage drop0.5V Total Power loss in LDO's60963090W Excessive current fraction0.10 Total excessive current power21901189W Total power to modules2408713083W Local power routing distance1.00m Max voltage drop on power wire0.20V Total power loss in cables1095597W Total power delivered2518213679W Power loops1356 Total loops current (all)27371491A Average loop current2.021.10A Minimum loop current (L4)1.540.81A Minimum wire diameter0.530.38mm Maximum loop current (L1)3.812.08A Maximum wire diameter0.660.49mm Loop voltage (typical)10.40 V Local power cable weight (Alu)2.081.14kg 17 8 chip modules 88% of chips 82% of power 4 chip modules: 12% of chips 18% of power Effective local cable reduction: 12kg/2.08kg= 5.8 (determined by number chips per module) If only 4 chip modules can be produced/used then power cabling mass will double: 4-2kg (Reduction = ~4)

18  Serial power looks attractive ◦ ~1/3 material in power cables ◦ ~1/3 power losses in cables (less worries about cabling cooling) ◦ No remote DC/DC with associated mass and integration problems ◦ Smart Shunt – LDO currently under design in 65nm ◦ Can possibly be even more advantageous:  Higher voltage drop on local power cables can possibly be supported.  When including the long distance power cabling of which some will be in forward acceptance ◦ Major worries: Noise injection, Failure propagation, Grounding  R&D and extensive testing required 18 Power systemTwo stage DC/DCIn-module SerialAcross-Module serialUnit Power scenarioCons.Opt.Cons.Opt.Cons.Opt. Active pixel chip power15.88.815.88.815.88.8kW On-chip DC/DC, LDO2.41.46.13.16.13.1kW Excessive power 2.21.22.21.2kW Total module power18.210.224.113.124.113.1kW Power cable losses2.81.61.10.60.90.5kW Total power21.011.825.213.725.013.6kW Power cabling mass5.332.992.081.141.790.97kg Power cabling in barrel0.450.250.170.090.150.08kg Remote DC/DC mass2.81.4 kg Local cable reduction1.5 (2.2)5.8 (4)6.9 Same Basic assumptions: 1m local power cabling counted Max 0.2V voltage drop on 1m wire Other materials: Chips + sensors: ~2kg Readout links: ~2-5kg Cooling, Mechanics, beam pipe: ?

19  In-module serial powering ◦ Advantages: Low mass cabling (~2kg), Low power dissipation on power cables (~1kW), Individual module powering. ◦ Disadvantages: High module power (~24kW). Different voltage potential of chips connected to same sensor. AC coupling required between chips on same module, Many (1300) power chains. ◦ Required R&D: Development of shunt-LDO (RD53). Verify if possible to have pixel chips at different potentials connected to one sensor.  Across-module serial powering ◦ Advantages: Low mass cabling (~2kg), Low power dissipation on power cables (~1kW), Few (160) power chains, All chips connected to same sensor at same potential, On-module communication without AC coupling, ◦ Disadvantages: High module power (~24kW). Failure propagation across modules. ◦ Required R&D: Development of shunt-LDO (RD53). Development of scheme/system to short circuit failing module ?.  Two stage DC/DC ◦ Advantages: Individual module powering, Low power on module (18kW). No AC coupling required between pixel chips. ◦ Disadvantages: High mass cabling (~5kg), Additional material (3kg) for remote DC/DC on service cylinder, High power losses on power cables (~3kW), Problem of available space on service cylinder for remote DC/DC converters. ◦ Required R&D: Development of rad hard on-chip DC/DC. Development of remote DC/DC. Detailed integration study of remote DC/DC on service cylinder.  One-stage on-chip /on-module DC/DC: ◦ Attractive if high conversion factor (6-10) can be obtained Any power system will need extensive test and verification 19

20  Based on initial guesses' and estimates ◦ Guesstimates of pixel chip power as function of pixel size, hit rates, Trigger rate, etc. ◦ Assuming 4 chip and 8 chip modules ◦ EXCEL sheets “engineering”  Not yet cross-checked by independent person/group  Further details in draft overview document attached to agenda 20

21 21

22  Modest rate (1.2Gbits/s) serial to remote LPGBT ◦ Rate that makes sense for input to LPGBT (10Gbits/s) ◦ Speed could be seriously limited by radiation damage ◦ Very low mass cable ◦ 2x (4x) as option ◦ Max 8 (4) per chip (high rate regions) ◦ Data merging from max 8 pixel chips (low rate regions)  3500 (7000) links, 2m twisted pair or flex cable ◦ 0.7 – 6 kg 22 100um sensors+100um pixel chips = ~2kg Si Alternatives: Single High rate (4-6Gbits/s) electrical link per chip to remote laser No use of LPGBT Opto conversion on pixel module Outer modules with “low” radiation and low rates and less space constraints

23 Cable option Wire size, diameter Wire resistance Mass for ~3500 cables % in signal pair % in shield/G nd % in insulator 36AWG Twisted pair, Cu, with shield 125um2.7 ohm5.8 kg27%40%33% 36AWG copper pair, Cu, no shield 125um2.7 ohm3.5 kg45%-55% Twisted pair Cu with Polyimide insulation 125um2.7 ohm1.8 kg92%-8% Twisted pair, Cu cladded Alu, Polyimide insulation 125um Alu 5um Cu 4.0 ohm0.7 kg83%-17% Kapton flat cable, Cu 35um gnd plane 140x35um 2 6.9 ohm4.0 kg15%55%20% Kapton flat cable, Cu 10um gnd mesh 140x35um 2 6.9 ohm1.5 kg40%10%50% Kapton flat cable, Alu 35um gnd plane 140x35um 2 11.5 ohm2.0 kg10%33%58% Kapton flat cable, Alu 10um gnd mesh 140x35um 2 11.5 ohm1.0 kg20%5%75% 23

24

25  150um x 150um hybrid pixels  3 layers, 2 disks  1m 2 sensitive surface  40MHz clock/sampling  Hit rate: ~200MHz/cm 2  100KHz trigger rate  250nm pixel ASIC ◦ Data buffering in end of column.  ~100Mrad, 10 15 neu/cm 2  Analogue readout  ~3KW power

26  2x hit rates: 500MHz/cm 2  Additional layer: 3 -> 4  ~1.5m 2  Modified 250nm pixel chip ◦ Increased EOC buffering ◦ Digital readout  Lower material  On detector DC/DC  Installation: 2016/2017  TDR: http://cds.cern.ch/record/1481838/fil es/CMS-TDR-011.pdf http://cds.cern.ch/record/1481838/fil es/CMS-TDR-011.pdf Current 3 layer Upgraded 4 layer Current 2 disk Upgraded 3 layer Radiation length

27  Installation: ~2022 ◦ Major upgrades of all CMS sub-detectors  10 x hit rates: ~3GHz/cm 2  Increased radiation hardness: 1Grad, 10 16 Neu/cm 2 (10years)  Better resolution: Smaller pixels: ~25um x 100um  Higher trigger rate: 10x  Pixel surface: 4 m 2  New pixel chip critical for time schedule of project

28  Requirements ◦ 25ns “sampling”, ◦ Amplitude information for each hit ◦ Rad hard: 1Grad, 10 16 Neu/cm 2 ◦ Small pixels: 25x100um 2 (50 x 100) ◦ Large chip: > 2cm x 2cm ◦ Very high hit rates: 1.5GHz/cm 2 ◦ Extensive on-chip data processing and buffering  In pixel (region) buffering and processing  Trigger rate: 100kHz – 1MHz  Trigger latency: 6 – 20us  Region of interest readout  High speed serial readout ◦ Low power: ½ - 1 W/cm 2 ◦ SEU tolerance ◦ Pixel sensor not yet determined !  65nm technology ◦ Radiation tolerant (to be verified for 1Grad) ◦ Good for large high density mixed signal ◦ Sufficiently dense: ½ analogue, ½ digital ◦ Affordable  CMS - ATLAS collaboration on 65nm for phase2 pixel chips ◦ Technology, Radiation hardness, IP blocks, Tools, Verification, etc. 256k pixels per chip Chip size: 2.6cm x 3cm Full high rate DAQ system on-chip

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