Work in progress – Do not publish RF&A/MS Summer 2011 Analog - carrier Frequency bands LF Analog (0-0.4GHz)RF (0.4-30GHz)mm-wave (30-300GHz)THz(>300GHz)

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Presentation transcript:

Work in progress – Do not publish RF&A/MS Summer 2011 Analog - carrier Frequency bands LF Analog (0-0.4GHz)RF (0.4-30GHz)mm-wave (30-300GHz)THz(>300GHz) Example applications Automotive controlsCellular60GHz point-to-pointNo products yet On-chip regulatorsWLANImagingCoordinate with ERD Power managementSerDesAutomotive radar ADC,DACWireless backhaul Broaden scope to include analog applications Contribute to Mixed-Signal section of System Drivers chapter Redefine chapter organization to strictly align by device technology – WAS: CMOS, Bipolar, Power-amp., mm-wave, MEMS, passives – IS: CMOS, Si Bipolar, III-V, Passives, HVMOS Apply M-t-M whitepaper methodology – Markets Applications Circuits Device Technology FOMs – Verify proscribed conditions are met: FOM, LEP, WAT, SHR, ECO

Work in progress – Do not publish Membership AMD Emerson Fang Freescale Jay John, Steve Cosentino, Jiangkai Zuo Hitachi Ltd. Digh Hisamoto HRL David Chow IBM Jack Pekarik, Dawn Wang, Mattias Dahlstrom, Jean-Olivier Plouchart, Taffy Kingscott, Natalie Feilchenfeld IEEE Anthony Immorlica Jr. Infineon Snezana Jenei, Carsten Ahrens Intel Ian Young, Jan-Erik Mueller ITRS Linda Wilson TowerJazz Semiconductor Ed Preisler National Semiconductor Wibo van Noort NIST Herb Bennett PMC-Sierra Brian Gerson Qualcomm Geoffrey Yeap Evgeni Gousev Raytheon Tom Kazior RF Micro Devices Julio Costa Samsung Hansu Oh Skyworks Peter Zampardi Sony Kaneyoshi Takeshita SRC David Yeh ST Pascal Chevalier Technology Research Institute Ginkou Ma Teledyne Scientific Bobby Brar TI Kamel Benaissa TSMC Douglas Pattullo Alex Kalnitsky UC Riverside Albert Wang Univ. of Toronto Sorin Voinigescu UT/Dallas Sam Shichijo New Members Toshiro Futatsugi, Fujitsu Yoshihiro Hayashi, Renesas Tatsuya Ohguro, Toshiba

Work in progress – Do not publish System Drivers Circuit-level FOMs related to technology FOMs -Low-noise amplifier (LNA) -Voltage-controlled oscillator (VCO) -Power amplifier (PA) -Analog-to-digital converter (ADC) -Serializer-Deserializer (SerDes) Example PA, LNA FOM

Work in progress – Do not publish CMOS Reflect the RF & Analog performance of PIDS technologies (HP and LSTP) f T, f MAX, NF MIN, analog gain, flicker noise, matching More rigorous attempt to predict effects of parasitic resistances and capacitances f T increases faster compared to 2009 roadmap f MAX lower in near-term reflecting parasitic effects

Work in progress – Do not publish Bipolar o Following changes in the table have occurred 1. Dropped the Power-Amplifier (PA) NPN (cf. scope). 2.Dropped the general analog NPN parameters i.e. 1/f noise and current matching (cf. scope). Added in text. 3.Completed an update of the HS-NPN roadmap to line up with the ongoing f T /f MAX trend and related W E scaling, in line with application requirements: a.Small decreased in the pace of f T and f MAX increase with a slowing down of W E reduction. b.Updated of all the other parameters accordingly. c.Added intrinsic slew rate (SL i ). d.Updated coloring. 4. Completed a major update of the HS-PNP roadmap to cover the applications of the revised scope: a.Increased of the breakdown voltages and decreased f T accordingly. b.Rewiewed the pace of the emitter width decrease. c.Updated of all the other parameters accordingly. d.Added collector-base breakdown voltage (BV CBO ). e.Added linearity efficiency cut-off frequency (f LE ). f.Updated coloring

Work in progress – Do not publish III-V technologies Analog, Microwave, mm-wave applications Emphasis on mm-wave Technology roadmaps truncated at expected end of scaling GaAs PHEMT(2015), GaAs MHEMT(2019), InP HEMT(2021), GaN HEMT(2021) and InP HBT(2023) FOMs depending on technology f T, f MAX, g m, V BD, Power, gain, efficiency NF MIN, G 10, 24, 60, 94GHz LNA NF, G 140, 220 GHz

Work in progress – Do not publish Passive devices Novelties/Changes to 2009/2010: Tables : On-chip passives only Resistors Capacitors Inductors Varactors Text : Emphasis on parasitics aware design Better definitions of (all) FoM Antennas Transmission lines using BEOL wiring Off-chip passives table omitted Coordinated/cross-referenced text with Assy &Packaging Inter-TWG : Interconnects and Assembly and packaging

Work in progress – Do not publish HVMOS New section in 2011 HVNMOS & HVPMOS Supporting Power-management & Display- driver applications FOM -BV DSS -R ON -Integrated CMOS node Truncate the roadmap at 90nm – uncertain of ever needing more dense CMOS