1 Possible integrated solutions to the power distribution puzzle in LHC upgrades F.Faccio, S.Michelis CERN – PH/MIC.

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Presentation transcript:

1 Possible integrated solutions to the power distribution puzzle in LHC upgrades F.Faccio, S.Michelis CERN – PH/MIC

F.Faccio, S.Michelis ACES workshop, March 07 2 Outline The power distribution puzzle in LHC upgrades (trackers) DC-DC converters with air-core inductors Low Drop Out regulators (LDO)

F.Faccio, S.Michelis ACES workshop, March 07 3 AC/DCDC/DC PP PP (with Lin.Reg. in some cases) PP Module 0.5-2m 13-15m 100m 1A/channel (analog or digital), round-trip cables, and sense to nearest regulation Material budget (X/Xo) Cooling Cable crowding Radiation Magnetic field Other general constraints: Overall efficiency Cost Reliability (single point of failure) Present power distribution schemes (in trackers)

F.Faccio, S.Michelis ACES workshop, March 07 4 More channels required, at lower Vdd, hence overall more current! More or thicker cables: Material budget ! Cooling ! Cable crowding! LHC upgrades - Requirements AC/DCDC/DC PP PP (with “LDO” in some cases) PP Module 0.5-2m 13-15m 100m Either >>1A/channel, or 1A/channel and more modules

F.Faccio, S.Michelis ACES workshop, March V AC/DCDC/DC PP (with DC/DC) PP Module (with DC/DC) 0.5-2m100m Same cables as today can bring more power, It requires efficient DC/DC on module for cooling V (or 4-8 V) AC/DCDC/DC PP Module (with DC/DC) 0.5-2m100m Small cables can bring all the power It requires efficient DC/DC 24 or 48 V PP Important considerations: Magnetic field, Radiation and Material Budget, Noise, plus EMI if inductor-based DC/DC Possible solutions based on DC-DC

F.Faccio, S.Michelis ACES workshop, March 07 6 On-module or on-chip… To filter switching noise and/or provide local regulation and protection (over-I, over-V, over-T), LDOs will be very useful – BUT they need to be radiation-hard! power LDOs on module (analog and digital power) power LDOs on chip

F.Faccio, S.Michelis ACES workshop, March 07 7 Present activities within PH-MIC Feasibility study for development of an integrated DC-DC buck converter based on air-core inductors (1 full-time student, Stefano Michelis) Collaboration with EPFL (1 “stagiaire” for 5 months) for the design of an LDO First steps towards the development of an on- chip LDO in 130nm technology

F.Faccio, S.Michelis ACES workshop, March 07 8 Aiming at demonstrating the feasibility of a fully integrated (except L and passive components) DC-DC buck converter DC-DC: Work in progress Vin=12-24 V Vout=1.5-3V I=1-2A Rad-hard technology Inductor Switching noise Controller architecture

F.Faccio, S.Michelis ACES workshop, March 07 9 Selection of a technology Design and test of transistors in the AMIS I3T80 technology Several different transistor topologies available for high-V applications (lateral, vertical) Layout “modified” to increase radiation tolerance

F.Faccio, S.Michelis ACES workshop, March NMOS better performance (lower gate and R on power dissipation ) Difficult to drive in the buck converter configuration (the main switch has the source floating => need of a bootstrap) ParametersNMOSPMOSUnits GS =3.3V, V DS =0.5V2542KΩ.μm V GS =0V, V DS =0V fF/um V GS =0V, V DS =0V fF/um V GS =0V, V DS =15V fF/um V GS =0V, V DS =15V fF/um Comparison between the available MOS transistors

F.Faccio, S.Michelis ACES workshop, March The main radiation-induced problem for the NMOS is the source-drain leakage current. Irradiation in all cases under bias, with Vgs=2 or 3.3V and Vds=0 or 14V. NMOS transistors (vertical) Vds=30V during measurement

F.Faccio, S.Michelis ACES workshop, March But leakage current can be effectively controlled with smart layout techniques NMOS transistors (vertical) Vds=30V during measurement

F.Faccio, S.Michelis ACES workshop, March Inductor: need of air core inductor because of high magnetic field (up to 4 T for CMS); ferromagnetic materials additionally can distort the static magnetic field MaterialMax. μSat B(T) Coldrolled steel2,0002,1 Iron5,0002,15 Purified iron180,0002,15 4% Silicon-iron30,0002,0 45 Permalloy25,0001,0 Hipernik70,0001,6 Monimax35,0001,5 Permendur5,0002,45 2V Permendur4,5002,4 Hiperco10,0002,42 Inductor core material

F.Faccio, S.Michelis ACES workshop, March Different commercial choices Coilcraft ABCD 16mm30mm14mm21mm Air-core inductors

F.Faccio, S.Michelis ACES workshop, March Study of noise implications Simulation of magnetic field to have a feeling of the physical extension of the field Hardware implementation of a DC-DC converter based on commercial components (controller, switchers, inductors). Evolutive concept where each component can be replaced by a custom developed one.

F.Faccio, S.Michelis ACES workshop, March Simulation of magnetic field Simulation of magnetic field for I=1A in 500nH air core-inductors (solenoid or toroid) Scale uT

F.Faccio, S.Michelis ACES workshop, March Hardware implementation 500nH inductor controller switchers Out capacitors

F.Faccio, S.Michelis ACES workshop, March Selection of an architecture for the controller Evaluation of the losses, and optimization Review of the adequate architectures and choice Full-custom implementation in an ASIC

F.Faccio, S.Michelis ACES workshop, March Design of LDO linear regulator 2 concepts carried on in parallel: Stand-alone component (300mA, Vout=1- 1.5V) On-chip macro (150mA, Vout=1.2V) Both in 130nm CMOS technology, and designed to be radiation tolerant Macros will be validated and can be modified for different specs

F.Faccio, S.Michelis ACES workshop, March Conclusion Possible integrated contributions to the power distribution problem: Integrated DC-DC buck converter (Vin=12-24V, I=1-2A) Based on air-core inductor and use of high-V CMOS technology with radiation tolerant design LDOs Stand-alone component, I=300mV On-chip “IP block” Work is in progress in these areas