1 WP2: on-detector power management F.Faccio, G.Blanchot, S.Michelis, S.Orlandi, C.Fuentes, B.Allongue CERN – PH-ESE
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group2 Outline Introduction Project structure Working Team Working Team Communication Communication Composition of WP2 Composition of WP2 Technical status WP2-1 WP2-1 WP2-2 and 2-3 WP2-2 and 2-3 Resources Conclusion
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group3 Distributing power Patch Panels (passive connectors ensuring current path between different cables. Regulation is very seldom used) Current path from PS to module (or more seldom star of modules) and return. Cables get thinner approaching the collision point to be compatible with material budget. PS No on-detector conversion. Low-voltage (2.5-5V) required by electronics provided directly from off-detector. Sense wire necessary for PS to provide correct voltage to electronics.
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group4 Distributing power
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group5 Distributing power with DC-DC The use of DC-DC converters allows the distribution of the power at higher voltage, while the converters provide locally the voltage level(s) required by the electronics DC-DC 10xV, IV, 10xI I 1xI 10xV DC-DC principle Principle distribution scheme
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group6 Challenges Converters to be placed inside the tracker volume Magnetic field (up to 4T) Radiation field (>10Mrd) Environment sensitive to noise (EMI) Commercial components are not designed for this radiation and magnetic environment, we need a custom development (ASICs) Space is very limited, and requirements for low mass stringent. High level of integration is mandatory Our goal: develop the ASICs necessary for the power distribution, and help their integration in full detector systems
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group7 Outline Introduction Project structure Working Team Working Team Communication Communication Composition of WP2 Composition of WP2 Technical status WP2-1 WP2-1 WP2-2 and 2-3 WP2-2 and 2-3 Resources Conclusion
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group8 The team CategoryWorking time (%) Comments F.FaccioStaff40 G.BlanchotStaff30 B.AllongueStaff30 S.MichelisMC fellow100Until 31/Oct/09 S.OrlandiFellow100Until 30/Jun/10 C.FuentesUpsa+HELEN100 Doctoral from 1/feb/09 (EU SLHC-PPfunds)
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group9 Communication and coordination In opposition to the early R&D phase of LHC, power distribution is today very fashionable 3 Working Groups: ATLAS, CMS, “common” CMS task force (first meeting today) Separate sessions at TWEPP, ATLAS and CMS upgrade workshops, ACES SLHC-PP within FP7 Parallel activities on other distribution schemes (serial powering) or different conversion approaches exist Expectations of the community are high (and impatient – maybe unnecessarily…) This all puts the development under constant pressure – and requires a very large amount of energy in reporting, coordination, discussions, …. Our activity is well known and reasonably well integrated in both ATLAS and CMS – and improving
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group10 Composition of WP2 Time frame: 3 years Split of the project in 3 parts WP2-1: Linear voltage regulation Development of “stand-alone” component for low current ( mA) applications Development of “stand-alone” component for low current ( mA) applications WP2-2: DC-DC conversion (corresponding to SLHC- PP deliverables) Development of converter prototype, integration in full-scale detector modules Development of converter prototype, integration in full-scale detector modules WP2-3: DC-DC conversion, Addition Aspects and activities not covered by SLHC-PP Aspects and activities not covered by SLHC-PP
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group11 Outline Introduction Project structure Working Team Working Team Communication Communication Composition of WP2 Composition of WP2 Technical status WP2-1 WP2-1 WP2-2 and 2-3 WP2-2 and 2-3 Resources Conclusion
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group12 WP2-1: Status Deliverables: Progress: Full schematic of the main regulation loop ready in IBM 130nm CMOS Protection circuits (over-V, over-I, over-T) almost complete in schematic The component does not look to be really needed now. Much more pressure on DC-DC development To be discussed at technical committee meeting (December?) Component specificationsReport31-Sep-08 Performance report on prototypePrototype, Report31-Mar-10 Full characterization, ready for series production Demonstrator31-Mar-11
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group13 WP2-2 and 2-3: deliverables WP2-2 Deliverables (in parenthesis also WP2-3) : Specific Additions in WP2-3 Consultancy to procure expertise in power electronics Transformer based on piezoelectric ceramic materials Second source CMOS technology Optimization of air-core inductor Evaluation report on conversion technologies, (including consultancy report) Report31-Mar-09 Prototypes of converters (and inductors) with viability report, (CMOS qualification report) Prototype, Report31-Mar-10 Integration in full-scale detector modulesDemonstrator31-Mar-11
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group14 Evaluation of conversion technologies Consultancy relationship established with PEL (Power Electronics Labs), University of Padova This collaboration proved extremely valuable 2 reports already produced. Design of 2 converters executed and first prototype manufactured Comparison of 5 different converter topologies taylored for our specific application. Choice restricted to 2 topologies (simple buck and 2-phase interleaved buck with voltage divider) Results from the measurements of the 2 converter prototypes (discrete components) 4 common working sessions organized: 2 in Padova and 2 at CERN (2-3 days each) Extremely efficient form of transfer of knowledge Large progresses in the project Outcome: we proposed at TWEPP a power distribution scheme for SLHC trackers
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group15 Proposed power distribution scheme Rod/stave 10-12V 2.5V Converter stage 1 Optoelectronics Stave controller 1.25V Converter stage 2 Detector 10-12V 2.5V 1.8V Converter stage 1 on- hybrid 2 Converter stage2 on-chip If I hybrid ~ I out_converter If I hybrid << I out_converter Detector 2.5V 1.8V 10-12V Detector 2.5V 1.8V Converter stage 1 on-stave Detector 2.5V 1.8V 2 Converter stage 2 on-chip
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group16 1.Single phase synchronous buck converter ↑ Simple, small number of passive components ↓ Larger output ripple for same C out ↓ RMS current limitation for inductor are output capacitance 2.4 phase interleaved synchronous buck converter ↑ Complete cancellation of output ripple for a conversion ratio of 4 (with small C out ) ↑ Smaller current in each inductor (compatible with available commercial inductors) ↓ Large number of passive components ↓ More complex control circuitry Different converter topologies (1/3) The following DC/DC step down converter topologies have been evaluated and compared in view of our specific application. V in V out Q1Q1 Q2Q2 L1L1 V in V out Q1Q1 Q2Q2 L1L1 Q3Q3 Q4Q4 L2L2 Q5Q5 Q6Q6 L3L3 Q7Q7 Q8Q8 L4L4 C out R load C out R load
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group17 3.Two phase interleaved synchronous buck converter with integral voltage divider ↑ Complete cancellation of output ripple for a conversion ration of 4 (with small C out ) ↑ Simpler control and smaller number of passive components than 4 phase interleaved 4.Multi-resonant buck converter ↑ Very small switching losses (zero voltage and zero current switching) ↓ To achieve resonance: Current waveforms have high RMS value => large conductive losses => lower efficiency Voltage waveforms have high peaks, possibly stressing the technology beyond max Vdd ↓ Different loads require complete re- tuning of converter parameters Different converter topologies (2/3)
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group18 5.switched capacitor voltage divider ↑ rather simple, limited number of passive components ↑ lack of inductor => good for radiated noise and for compact design ↓ No regulation of the output voltage, only integer division of the input voltage ↓ Efficiency decreases with conversion ratio (larger number of switches) ↑ Good solution for ratio = 2, for which high efficiency can be achieved Different converter topologies (3/3)
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group19 Conversion stage 1: topology Waveforms of the different topologies have been computed with Mathcad, and conversion losses have been estimated for each of them in the same conditions: V in = 10V, P out = 6W, V out = 2.5V (step down ratio = 4), use of AMS 0.18um technology with approximate formula to account for switching losses Topologies Efficiency Components needed Number of Switches Number of Capacitors Number of Inductors Buck converter phase Interleaved Buck phase Interleaved Buck + VD Multiresonant Buck Cascaded Switched Capacitor The best compromise in terms of efficiency, number of components required, complexity and output ripple is the 2 phase interleaved buck with integrated voltage divider.
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group20 DIGITAL, V out =1.8VANALOG, V out =2.5V Implementation: conversion stage 1 The final result of our study is that, for the development of a unique ASIC conversion stage 1 for both analog and digital power distribution, the best solution is: 2-phase interleaved buck with integrated voltage divider Switching frequency = 1 MHz On-resistance of switching transistors = 30 m The inductor can be chosen for the specific output current wished in the application, achieving the efficiency estimated in the graphs below for the AMS 0.18 technology (Coilcraft RF 132 series inductors are used)
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group21 Implementation: conversion stage 2 Two converters to be embedded on each chip Output current rather modest ( mA) Inductor-based converters not envisageable: With on-chip inductors (high ESR) the efficiency would be extremely low The use of several discrete inductors per ASIC is not desirable – already only for system integration purposes Switched capacitor converters more suitable Acting as voltage divider (÷2) They unfortunately do not provide regulation, which must be relied on from conversion stage 1 Achievable efficiency has been estimated, then refined with a quick simulation in a 130nm technology (use of I/O transistors) Efficiency (Vin=1.8V, Vout=0.9V, Iload=166mA, f=20MHz) = 93% It should be pointed out that no study on the optimization of this converter has been made – one only topology, with one fixed frequency has been studied (efficiency can be improved further by decreasing the frequency, for instance). V in V out =V in /2 Q1Q1 Q2Q2 Q3Q3 Q4Q4 gnd
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group22 WP2-2 and 2-3: deliverables WP2-2 Deliverables (in parenthesis also WP2-3) : Specific Additions in WP2-3 Consultancy to procure expertise in power electronics Transformer based on piezoelectric ceramic materials Second source CMOS technology Optimization of air-core inductor Evaluation report on conversion technologies, (including consultancy report) Report31-Mar-09 Prototypes of converters Prototypes of converters (and inductors) with viability report, (CMOS qualification report) Prototype, Report31-Mar-10 Integration in full-scale detector modulesDemonstrator31-Mar-11
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group23 Prototype of converters Several prototype converters using discrete components have been manufactured Main objective: study EMC First integrated prototype developed and manufactured in a CMOS 0.35um technology with high-V module
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group24 ASIC development ASIC designer: Stefano Michelis Prototype for “conversion stage 1” First prototype designed and manufactured in AMIS I3T80 technology Simple buck topology V in up to 10V V out =2.5V I out up to 1.5A switching frequency MHz ASIC included main functions only (switches, control circuitry) External compensation network, reference voltage and sawtooth generator required
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group25 ASIC Prototype performance ASIC mounted on a custom PCB (chip on board) Functionality is OK, it provides regulated output at 2.5V for different loads Efficiency limited to 70% max. Known limitations from the use of vertical transistors with large Ron Additional losses probably due to “shoot-through” (verification ongoing) Noise performance very reasonable Used already to power CMS endcap tracker modules (RWTH Aachen) Second version – more complete and with different power transistors – to be submitted at the beginning of December
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group26 WP2-2 and 2-3: deliverables WP2-2 Deliverables (in parenthesis also WP2-3) : Specific Additions in WP2-3 Consultancy to procure expertise in power electronics Transformer based on piezoelectric ceramic materials Second source CMOS technology Second source CMOS technology Optimization of air-core inductor Evaluation report on conversion technologies, (including consultancy report) Report31-Mar-09 CMOS qualification report Prototypes of converters (and inductors) with viability report, (CMOS qualification report) Prototype, Report31-Mar-10 Integration in full-scale detector modulesDemonstrator31-Mar-11
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group27 CMOS technology Full radiation characterization of AMIS IT380 technology (0.35um CMOS) completed Report available Performance not really matching requirements Contacts established, in synergy with WP1, with two alternative providers STM, possibly interested to a common development. 2 of their technologies selected, samples provided. Samples are being irradiated now AMS, developing a new 0.18um high-V CMOS technoloogy with IBM. Participation in first MPW confirmed, but delayed by 6 months to 4/09 Contacts established with another alternative supplier, IHP Contact established via CNM Barcelona (ATLAS), now in coordinated way with RTWH Aachen (CMS) Provided samples are being irradiated now IHP willing to collaborate in enhancing and maintaining radiation hardness Design of test chip in collaboration with CNM and IHP is in progress Objective: select one technology with appropriate characteristics, and move ASIC prototyping in that technology as soon as possible
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group28 WP2-2 and 2-3: deliverables WP2-2 Deliverables (in parenthesis also WP2-3) : Specific Additions in WP2-3 Consultancy to procure expertise in power electronics Transformer based on piezoelectric ceramic materials Second source CMOS technology Optimization of air-core inductor Optimization of air-core inductor Evaluation report on conversion technologies, (including consultancy report) Report31-Mar-09 Prototypes ofinductors Prototypes of converters (and inductors) with viability report, (CMOS qualification report) Prototype, Report31-Mar-10 Integration in full-scale detector modulesDemonstrator31-Mar-11
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group29 Optimization of air-core inductors Inductors are crucial components for the converter Air-core inductors have to be used since ferromagnetic materials saturate in the high magnetic field of CMS/ATLAS Since the current flowing is not dc, they are emitters of magnetic field. This can induce noise Their parasitic resistance strongly influences efficiency Simulation studies are made to compare magnetic field and ESR of different inductor designs After choice of design, prototypes have to be manufactured This will likely require establishing relationship with industry (custom coil manufacturers), unless a planar PCB solution is chosen
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group30 Which inductor to use? Air-core inductors can be manufactured in different configurations (planar, solenoidal, thoroidal, ….) and a choice should be made Value: reasonably limited in range nH Equivalent resistance (ESR) determines converter efficiency to sensible extent Planar (on PCB) ESR~100m Solenoidal ESR~20-30m Thoroidal ESR~20-30m
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group31 Air core solenoid 11mm far from the solenoid: 5µT18nT Not shielded Shielded
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group32 Air core toroid 11mm far from the centre of the toroid 11mm far from the toroid: 6.6µT
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group33 Example PCB Toroid 11mm far from the toroid: 19µT70nT Not shielded Shielded This PCB toroid was developed at Bristol, Aknowledegment to David Cussans
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group34 WP2-2 and 2-3: deliverables WP2-2 Deliverables (in parenthesis also WP2-3) : Specific Additions in WP2-3 Consultancy to procure expertise in power electronics Transformer based on piezoelectric ceramic materials Second source CMOS technology Optimization of air-core inductor Evaluation report on conversion technologies, (including consultancy report) Report31-Mar-09 Prototypes of converters (and inductors) with viability report, (CMOS qualification report) Prototype, Report31-Mar-10 Integration in full-scale detector modules Demonstrator31-Mar-11
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group35 Integration in detector modules Main issues for integration: EMC and physical space EMC Measurements of noise (conducted and radiated) on converter prototypes Module-level RWTH Aachen with CMS TEC CERN with TOTEM Si Strip modules
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group36 Conducted noise measurement Reference test bench developed within ESE Well defined measurement methods for reproducible and comparable results. Independence from the system and from the bulk power source. Arrangement of cables, input and output filter (LISN) around the converter under test, all above a ground plane.
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group37 Noise measurement on different CERN prototypes Proto2 Proto3 Proto4 All the measurement were made in these conditions: Vin=10V, Vout=2.5V, Iout=1A and f sw =1Mhz Proto 1,2,3 were developed at CERN with the same controller. PCB layout and parasitic component choice was improved Proto 4’s PCB was designed in Aachen and the ASIC (in the red spot) was designed at CERN ~46dBµA ~51dBµA ~58dBµA ~62dBµA Proto1
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group38 TOTEM Front-End system supplied with DC-DC converters Powering a detector module Expose the front-end system to the DC-DC converter conducted noise (Common Mode and Differential Mode currents)
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group39 WP2-2 and 2-3: deliverables WP2-2 Deliverables (in parenthesis also WP2-3) : Specific Additions in WP2-3 Consultancy to procure expertise in power electronics Transformer based on piezoelectric ceramic materials Transformer based on piezoelectric ceramic materials Second source CMOS technology Optimization of air-core inductor Evaluation report on conversion technologies, (including consultancy report) Report31-Mar-09 Prototypes of converters (and inductors) with viability report, (CMOS qualification report) Prototype, Report31-Mar-10 Integration in full-scale detector modulesDemonstrator31-Mar-11
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group40 Piezoelectric transformers 2-days workshop organized in April at CERN Held with Limiel (Dk) – consultancy firm on piezoceramic materials and (in particular) their applications Nothing similar to what we would need exists – requirement for developing both the custom ceramic device AND the driving circuitry No on-field reliability data exist!! Further difficulties emerged during the workshop Need for an output rectifier (difficult to achieve high efficiency for low voltage) Since the capacitance of the transformer has to be matched to the load, its size gets unpractical in our application (several cm per side, very thin) The transformer can not cope with sudden output open – too much energy stored that can not be dissipated. This is a safety concern Conclusions It looks very unlikely that an attractive solution for our application can be found In any case, an activity aimed purely at demonstrating the feasibility of such very innovative approach would require our full resources We decided to abandon this solution
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group41 Outline Introduction Project structure Working Team Working Team Communication Communication Composition of WP2 Composition of WP2 Technical status WP2-1 WP2-1 WP2-2 and 2-3 WP2-2 and 2-3 Resources Conclusion
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group42 Resources AllocationSpent To be spent before 31/12 Foreseen balance 31/12 WP2-1 and K94 K18 K48 K WP 2-2 CERN15 K -- WP 2-2 EU65 K3 K24K38 K Funds Manpower - Very good, young and motivated team. Experience acquired through consultancy - Size adequate (addition of 1 fellow in mid-09) - 1 staff LD crucial to ensure continuity of the project (main designer is MC fellow)
PH Theme 3 meeting November 11, 2008CERN - PH dept – ESE group43 Conclusion Excellent progress in the first months of activity Work started also on deliverables for 2011! Work started also on deliverables for 2011! WP activity well on-budget Activity focused on DC-DC converters – following demand from the experiments If appropriate continuity is ensured in terms of manpower and funds, WP2 will provide a viable solution for the SLHC experiments