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Deep-submicron FD-SOI for front-end application. Hirokazu Ikeda ikeda.hirokazu@jaxa.jp Institute of space and astronautical science Japan aerospace exploration agency. Abstract.
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Deep-submicron FD-SOI for front-end application Hirokazu Ikedaikeda.hirokazu@jaxa.jpInstitute of space and astronautical scienceJapan aerospace exploration agency STD6 @Carmel, CA
Abstract SOI devices are free from parasitic PNPN structure, and, hence, intrinsically immune to single event latch-ups. Moreover SOI devices are located on a very thin silicon layer, the energy deposit by impinging particle is relatively small, and, then, the single event upsets and/or single-event transients are manageable with an appropriate design strategy. When designing front-end circuits with an FD-SOI, we can take benefits such as small floating-body effect, superior sub-threshold characteristics and small temperature coefficient as well as common nature of SOI devices, i.e. small parasitic capacitance, low junction leakage, decrease in substrate coupling noise, and reduction of silicon area. In order to confirm these benefits and to identify possible issues concerning front-end circuits with a deep sub-micron FD-SOI, we have submitted a small design to OKI via the multi-chip project service of VDEC, the university of Tokyo. The initial test results and future plan for development are presented in this talk. STD6 @Carmel, CA
Team organization JEM/ISS Possible application for solar system exploration, and deep-space observation Possible application for Super-B, SLHC, ILC and material science H.Ikeda, H.Hayakawa, K.Hirose, Y.Kasaba, T.Takahashi, T.Takashima, H.Tomita JAXA Y.AraiA, K.HaraB, Y.IkegamiA, H.IshinoC,T.KawasakiD, T.KohrikiA, E.MartinE, H.MiyakeF, A.MochizukiB, H.TajimaF, O.TajimaA, S.TeradaA, T.TsuboyamaA, Y.UnnoA, H.UshirodaA, G.VarnerE KEKA, U.TsukubaB, TITC, Niigata UD, U. HawaiiE, Osaka UF, SLACF STD6 @Carmel, CA
Contents for talk • Introduction • TEG fabrication • Circuit and operation • Towards radiation-hardness assurance • Conclusion STD6 @Carmel, CA
1. Introduction Entering into late 1990's, the trend curve of a bulk CMOS process tends to go behind the Moore's law, and, hence, the manufactures are eager to find a way to recover development speed. There exists a general trend : Post-scaling technology…..SOI/SOS, Strained-Si, 3D-tr, Cu, High-k, Low-k….. SOI CMOS is then revisited to reveal its performance over an existing bulk CMOS; the SOI CMOS eventually shows up as a successor of the CMOS process inheriting well-matured fabrication technologies for a bulk CMOS. ・Full dielectric isolation: Latch-up free, Small area ・Low junction capacitance: High speed, Low power ・Low junction leakage: High Temp. application ・Decrease in substrate coupling: A/D mixed application ・High soft error immunity: Rad-hard application STD6 @Carmel, CA
Depletion Layer FD-SOI STD6 @Carmel, CA
2. TEG fabrication 0.15-um FD-SOI Processed by Oki Elec. Ind. Co., Ltd SOI: 50 nm, BOX: 200 nm, 6”wafer(UNIBONDTM,SOITEC) Vdd: 1.0 V/1.8 V, Vth: 0.18/-0.25 for LVT Metal: 5-layers, Capacitor: MIM Option: Thick metal 4,5,6 inch wafer, CMOS/Bipolar 6,8 inch wafer Mass production JAXA/MHI route (0.2 um) c/o K.Hirose VDEC route(0.15 um) VLSI design & education center, The university of Tokyo KEK route (0.15 um W/ pixel implant) c/o Y.Arai Research ISAS, JAXA STD6 @Carmel, CA
2.4 mm Charge amplifier TOT amplifier-1 TOT amplifier-2 Trans-impedance amplifier STD6 @Carmel, CA
3. Circuit and operation nMOS (LVT) input Id=100-500 uA W/L=5/0.5 M=360 Cox*W*L=12.5 pF gm= 11.5 mS Gain-boost STD6 @Carmel, CA
Short decay Long decay Chain1 The leakage current of the FB circuit determines the slowest decay. STD6 @Carmel, CA
Good dynamic range 500 mV 200 mV nchl,pchl nchv,pchv Adjustment to balance Leakage current STD6 @Carmel, CA
4 fC 40 fC Chain2 STD6 @Carmel, CA
Small overshoot 4 fC 40 fC Chain3 Small overshoot as expected STD6 @Carmel, CA
-8 fC 2 fC 8 fC Chain4 1 V CMOS D/A interference is very severe. STD6 @Carmel, CA
4. Towards radiation-hardness assurance Total dose:radiation hard? Not necessarily the case for gate edge and/or BOX. H-gate (Enclosed gate?): ready to use Voltage on handle wafer: control of Vth Future of SOI-CMOS Single event: radiation hard? Not necessarily the case. Appropriate design-by-hardning is required. STD6 @Carmel, CA
As a first step….. DUT Y.Ikegami et al. DUT STD6 @Carmel, CA
5. Conclusion • FD-SOI analog front-end circuits are examined under a joint effort • of JAXA , KEK and related institutes as a part of the SOI-pixel detector • development and/or future solar system/deep-space exploration. • The FD-SOI TEG circuits are proved to work even with very low • Vdd voltage thanks to stable low threshold transistors. • Minor issues are identified, and confirmed to be fixed in the second RUN. • The third RUN is scheduled in Dec, where we are going to proliferate the • TEG design for a tracking application as well as spectropscopic use. • Radiation hardness is still an issue to be examined in term of total dose • and SEU/SET. • 5) Road-map for the SOI technology is on the way of the post-scaling • technology, which conforms with application in a harsh environment • in space and high energy physics. STD6 @Carmel, CA
Large dynamic range STD6 @Carmel, CA
Pulse width is sensitive to the leakage current due to the ESD pad! The leakage current is adjusted by moving the VSS voltage for the ESD pad. 18 STD6 @Carmel, CA