Augmenting heavy and power-hungry data collection equipment with lighter, smaller wireless sensor network nodes leads to faster, larger deployments. Arrays comprising dozens of wireless sensor nodes are now possible, allowing scientific studies that aren't feasible with traditional instrumentation. Designing sensor networks to support volcanic studies requires addressing the high data rates and high data fidelity these studies demand. The authors' sensor-network application for volcanic data collection relies on triggered event detection and reliable data retrieval to meet bandwidth and data-quality demands.
[1] The first probabilistic tsunami flooding maps have been developed. The methodology, called probabilistic tsunami hazard assessment (PTHA), integrates tsunami inundation modeling with methods of probabilistic seismic hazard assessment (PSHA). Application of the methodology to Seaside, Oregon, has yielded estimates of the spatial distribution of 100-and 500-year maximum tsunami amplitudes, i.e., amplitudes with 1% and 0.2% annual probability of exceedance. The 100-year tsunami is generated most frequently by far-field sources in the Alaska-Aleutian Subduction Zone and is characterized by maximum amplitudes that do not exceed 4m,with an inland extent of less than 500 m. In contrast, the 500-year tsunami is dominated by local sources in the Cascadia Subduction Zone and is characterized by maximum amplitudes in excess of 10 mand an inland extent of more than 1k m. The primary sources of uncertainty in these results include those associated with interevent time estimates, modeling of background sea level, and accounting for temporal changes in bathymetry and topography.N onetheless, PTHA represents an important contribution to tsunami hazard assessment techniques; viewed in the broader context of risk analysis, PTHA provides amethod for quantifying estimates of the likelihood and severity of the tsunami hazard, which can then be combined with vulnerability and exposure to yield estimates of tsunami risk.
and 5 highlight how relaxed gate pitch improves fT which results from not only lower capacitance from wider gate-toWe report record RF performance in 45-nm silicon-oncontact spacing but also enhanced stress response (higher insulator (SOI) CMOS technology. RF performance scaling transconductance gm) of the device. Fig. 6 shows peak fTvs. with channel length and layout optimization is demonstrated. I/Lpoly for SOI CMOS from 90 to 45-nm nodes, Peak fT's of 485 GHz and 345 GHz are measured in floatingdemonstrating that RF performance scaling continues with body NFET and PFET with nearby wiring parasitics (i.e., gateLpoly in deep sub-lOOnm CMOS technologies. Figs. 7 and 8 to-contact capacitance) included after de-embedding, thus show the gm and Cgate (= Cgs + Cgd) vs. I/Lpoly extracted at representing FET performance in a real design. The measured peak fT condition for 45-nm SOI NFETs and PFETs, fT's are the highest ever reported in a CMOS technology. Bodyindicating the well controlled channel with Lpoly. contacted FETs are also analyzed that have layout optimized Source/drain contact pitch as well as gate poly pitch can be for high-frequency analog applications. Employing a notched optimized for RF applications, and Figs. 9 and 10 show the body contact layout, we reduce parasitic capacitance and gate measuredfT and gm for minimum poly pitch SOI NFETs and leakage current significantly, thus improving RF performance PFETs with an Lp of 31 nm as a function of gate bias, with low power. For longer than minimum channel length and a where wider source/drain contact pitches result in higherfT, body-contacted NFET with notched layout, we measure a peak due to the lowering of gate-to-contact capacitance with fT of 245 GHz with no degradation in critical analog figures of fewer contacts. Note also in Figs. 9 and 10 that the gm of the merit, such as self-gain. device is not affected much by the potential increase of source/drain resistance with fewer contacts. Introduction B. Body-contacted SQL FET analog/RF Performance This high-performance 45-nm SOI technology features 1.16 nm gate oxide, dual stress liners (DSL), eSiGe PFET, advancedIn high-frequency analog circuits, device self-gain (gm activation annealing, and stress memorization techniques over output conductance gds) and matching between (SMT) [1]. Advanced immersion lithography employed neighboring devices are important. For such consideration, provides good channel length control and supports multiple we investigate SOI NFETs with longer than minimum gate pitches. To investigate the suitability of this high channel length (for high self-gain) and a body contact (for performance CMOS technology for millimeter-wave digital good matching due to reduced VBS fluctuation). Fig. 11 and analog system-on-chip (SoC) applications [2, 3, 4], Sshows the measured self-gain as a function of gate bias for a parameter measurements at frequencies up to 110 GHz were floating-body NFET with 32 nm Lp01y and body-contacted performed to analyze RF/analog characteristics of partially-NFET w...
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.