A 440-ps 64-bit adder in 1.5-V/0.18-μm partially depleted SOItechnology

A 64-bit adder in 1.5-V/0.18-μm partially depleted SOI technology, CMOS8S, and techniques to maintain performance are described. CMOS7S SOI, a 1.8-V/0.22-μm partially depleted SOI technology, achieves a 28% speed increase over bulk CMOS7S, and CMOS8S SOI delivers an additional 21%. In a 660-MHz CMOS8S SOI processor, the adder compensates for floating body effects in SOI devices which cause history effects, bipolar currents, and lower noise margins on dynamic circuits     

4- and 13-GHz tuned amplifiers implemented in a 0.1-μm CMOStechnology on SOI, SOS, and bulk substrates

Four- and 13-GHz tuned amplifiers have been implemented in a partially scaled 0.1-1 μm CMOS technology on bulk, silicon-on-insulator (SOI), and silicon-on-sapphire (SOS) substrates. The 4-GHz bulk, SOI, and SOS amplifiers exhibit forward gains of 14, 11, and 12.5 dB and F_min's of 4.5 (bulk) and 3.5 db (SOS). The 13-GHz SOS and SOI amplifiers exhibit gains of 15 and 5.3 dB and F_unn's of 4.9 and 7.8 dB. The 4-GHz bulk amplifier has the highest resonant frequency among reported bulk CMOS amplifiers, while the 13-GHz SOS and SOI amplifiers are the first in a CMOS technology to have tuned frequencies greater than 10 GHz. These and other measurement results suggest that it may be possible to implement 20-GHz tuned amplifiers in a fully scaled 0.1-1 μm CMOS process     

ESD reliability and protection schemes in SOI CMOS output buffers

The electrostatic discharge (ESD) protection capability of SOI CMOS output buffers has been studied with Human Body Model (HBM) stresses. Experimental results show that the ESD voltage sustained by SOI CMOS buffers is only about half the voltage sustained by the bulk NMOS buffers. ESD discharge current in a SOI CMOS buffer is found to be absorbed by the NMOSFET alone. Also, SOI circuits display more serious reliability problem in handling negative ESD discharge current during bi-directional stresses. Most of the methods developed for bulk technology to improve ESD performance have minimal effects on SOI. A new Through Oxide Buffer ESD protection scheme is proposed as an alternative for SOI ESD protection. In order to improve ESD reliability, ESD protection circuitries can be fabricated on the SOI substrate instead of the top silicon thin film, after selectively etching through the buried oxide. This scheme also allows ESD protection strategies developed for bulk technology to be directly transferred to SOI substrate.<>     

Modeling of the bulk versus SOI CMOS performances for the optimal design of APS circuits in low-power low-voltage applications

In this paper, we present the top-down design of an active pixel sensor (APS) circuit using an analytical model of its architecture. The model is applied to compare the performances of bulk versus silicon-on-insulator (SOI) CMOS processes and devices on the designs and performance of several 50-frames/s imagers in 2-/spl mu/m and 0.25-/spl mu/m CMOS with different pixels array sizes. For 2-/spl mu/m SOI, results show a reduction by two of the power consumption and a dynamic range increase of 0.85 V under a 3-V supply. This results in an SNR of 79 dB instead of 76. Fixed pattern noise (FPN) is also reduced from 2.7 to 1.8 mV which represents 0.26% and 0.08% of the dynamic range, respectively. For 0.25-/spl mu/m CMOS SOI, results show a reduction by 6.5 of the power consumption, FPN more than five time better, and a dynamic range increase of 0.29 V under a 1.5-V supply. However, because of the increase of the thermal noise due to the particular design choice, an SNR of 60.3 dB is achieved compared to 63 in bulk. A better SNR in SOI than in bulk can be achieved but at the expense of power consumption and FPN. However, this could be combined with an increase in pixels number in SOI compared to bulk. Potential results achievable in SOI have to our knowledge never been reached by bulk APS imagers up to now.     

Total dose radiation effects of hybrid bulk/SOI CMOS active pixel with buried channel SOI source follower

A CMOS active pixel with pinned photodiode which used in-pixel buried-channel (BC) transistor has been reported, and the characteristic of CMOS image sensor with in-pixel buried-channel transistor was carried out. In this paper, we have a research on a hybrid bulk/silicon-on-insulator (SOI) CMOS active pixel with pinned photodiode which use buried channel SOI NMOS Source Flower (SF) by simulation. We study the basic characteristics of buried-channel SOI NMOS and the characteristics of CMOS active pixel optimized by using in-pixel buried-channel SOI transistor under radiation. The results show that, compared to the conventional active pixel with the standard surface-channel (SC) SOI NMOS SF, the dark random noise of the pixel which uses in-pixel buried channel SOI NMOS SF can be reduced under the radiation and the output swing is improved.     

Fault detection in CMOS/SOI mixed-signal circuits using the quiescent current test

Main stream bulk CMOS and the variants of silicon-on-insulator (SOI) CMOS technologies are discussed with respect to testing for the quiescent current of mixed-signal integrated SOI circuits. The 2–3 times lower static power consumption in fully depleted CMOS/SOI compared to bulk CMOS allows quiescent current testing also for high performance analogue circuits at an acceptable defect resolutions. From first simulations and technological considerations, it turned out that quiescent current tests are able to detect not only commonly known defects, but also SOI specific defects such as self-heating, kink-effect or the parasitic bipolar behaviour. It is further shown that in partially depleted thick-film SOI, the kink-effect and parasitic bipolar transistor support the quiescent current test for some specific defects as they elevate the defective quiescent current level. In fully depleted kink-free SOI circuits, the kink-effect may occur due to process failures but then can be detected by quiescent current tests. A special fault simulation model for the kink-effect is presented. The I_ccq test technique is studied for a CMOS/SOI Miller operational amplifier. Normal 6-σ variation of the aspect ratio and the threshold voltage do not jeopardise the defect detection in the quiescent current. First, results confirm the good detection capabilities of the quiescent current test, in particular, of failures which are not visible in the output voltage.     

采用CoSi2 SALICIDE结构CMOS/SOI器件辐照特性的实验研究

讨论了ＣｏＳｉ２ＳＡＬＩＣＩＤＥ结构对ＣＭＯＳ／ＳＯＩ器件和电路抗γ射线总剂量辐照特性的影响。通过与多晶硅栅器件对比进行的大量辐照实验表明,ＣｏＳｉ２ＳＡＬＩＣＩＤＥ结构不仅可以降低ＣＭＯＳ／ＳＯＩ电路的源漏寄生串联电阻和局域互连电阻,而且对ＳＯＩ器件的抗辐照特性也有明显的改进作用。     

A stacked CMOS technology on SOI substrate

A stacked CMOS technology fabricated on semiconductor-on-insulator (SOI) wafers with the p-MOSFET on the SOI film and the n-MOSFET on the bulk substrate is demonstrated. The technology provides a number of advantages, including: 1) single crystal multi-layer of active devices; 2) self-aligned double-gate p-MOSFET with thick source/drain and thin channel regions; 3) self-aligned channel region of n-MOSFET to p-MOSFET stacked perfectly on top of each other; 4) significant area saving; and 5) reduced interconnect distance and loading. Experimental results show that the fabricated double-gate p-MOSFET has a nearly ideal subthreshold swing and almost the same current drive as the n-MOSFET with the same lateral width, resulting in a highly compact and completely overlap stacked CMOS inverter.     

Grasping SOI floating-body effects

It is important to understand what the floating-body effects are and how they affect device and circuit behavior. In this regard, this article qualitatively explains the device physics underlying DC and transient floating-body effects, clearly implying their influence on circuits, and thereby giving good insight into PD/SOI CMOS design issues. The article also notes special but practical device and circuit designs for controlling floating-body effects, showing through simulation how PD/SOI offers a significant performance advantage over bulk silicon in low-voltage applications, thereby conveying an assurance that reliable SOI CMOS design is feasible     

基于全耗尽技术的SOI CMOS集成电路研究

介绍了电路的工作原理,对主要的延迟和选通控制单元及整体电路进行了模拟仿真,证明电路逻辑功能达到设计要求。根据电路的性能特点,采用绝缘体上硅结构,选用薄膜全耗尽SOICMOS工艺进行试制。测试结果表明：与同类体硅电路相比,工作频率提高三倍,静态功耗仅为体硅电路的10％,且电路的101级环振总延迟时问也仅为体硅电路的20％,实现了电路对高速低功耗的要求。     

Advanced technologies for optimized sub-quarter-micrometer SOI CMOSdevices

Two manufacturable technologies of fully-depleted (FD) thin-film silicon-on-insulator (SOI) MOSFET's for low-power applications are proposed in this paper. To maintain high current drive while aggressively thinning down the SOI film, silicide is to be formed on Ge-damaged silicon layers. Ge preamorphization facilitates silicide formation at low temperature (~450°C) and effectively controls the silicide depth without void formation. It also reduces the floating body effect. In addition, a reliable gate work-function engineering is introduced for good threshold voltage management. A p⁺SiGe/Si stack gate alleviates the threshold voltage instability of SOI due to film thickness nonuniformity and broadens the design window for channel doping. These advanced technologies, compatible with existing bulk CMOS technology, are integrated into SOI CMOS process. Excellent electrical device results are presented     

Heating effects of clock drivers in bulk, SOI, and 3-D CMOS

Steady-state and transient thermal behavior of the highest power density element in systems and chips-the clock driver-in bulk, silicon-on-insulator (SOI), and three-dimensional (3-D) CMOS is examined. Despite significant metal wiring, a majority of the heat conducts through the buried oxide (BOX) in SOI and the buried interconnect layer in 3-D CMOS. 3-D CMOS has the potential to improve substantially over SOI CMOS in thermal behavior by increasing the wiring density directly beneath the clock driver. Temperature mismatch (important for analog applications) between device planes in 3-D CMOS occurs within a characteristic length, which is as large as 13 /spl mu/m for clock drivers. These results suggest advantages and architectural options for the design of high-power devices in 3-D integration.     

Improving bulk FinFET DC performance in comparison to SOI FinFET

The implementation of FinFET structure in bulk silicon wafers is very attractive due to low-cost technology and compatibility with standard bulk CMOS in comparison with silicon-on-insulator (SOI) FinFET. SOI and bulk FinFET were analyzed by a three-dimensional numerical device simulator. We have shown that bulk FinFET with source/drain-to-body (S/D) junctions shallower than gate-bottom has equal or better subthreshold performance than SOI FinFET. By reducing S/D junction depth, fin width scaling for suppression of short-channel-effects (SCEs) can be relaxed. On-state performance has also been examined and drain current difference between the SOI and bulk FinFET at higher body doping levels has been explained by investigating enhanced conduction in silicon-oxide interface corners. By keeping the body doping low and junctions shallower than the gate-bottom, bulk FinFET characteristics can be improved with no increase in process complexity and cost.     

Fully-Depleted SOI CMOS Technology for Low-Voltage Low-Power Mixed Digital/Analog/Microwave Circuits

This paper demonstrates that fully-depleted (FD) silicon-on-insulator (SOI) technology offers unique opportunities in the field of low-voltage, low-power CMOS circuits. Beside the well-known reduction of parasitic capacitances due to dielectric isolation, FD SOI MOSFETs indeed exhibit near-ideal body factor, subthreshold slope and current drive. These assets are both theoretically and experimentally investigated. Original circuit studies then show how a basic FD SOI CMOS process allows for the mixed fabrication and operation under low supply voltage of analog, digital and microwave components with properties significantly superior to those obtained on bulk CMOS. Experimental circuit realizations support the analysis.     

用SOI技术提高CMOS SRAM的抗单粒子翻转能力

提高静态随机存储器（SRAM）的抗单粒子能力是当前电子元器件抗辐射加固领域的研究重点之一。体硅CMOS SRAM不作电路设计加固则难以达到较好抗单粒子能力,作电路设计加固则要在芯片面积和功耗方面做出很大牺牲。为了研究绝缘体上硅（SOI）基SRAM芯片的抗单粒子翻转能力,突破了SOI CMOS加固工艺和128kb SRAM电路设计等关键技术,研制成功国产128kb SOI SRAM芯片。对电路样品的抗单粒子摸底实验表明,其抗单粒子翻转线性传输能量阈值大于61．8MeV／（mg／cm^2）,优于未做加固设计的体硅CMOS SRAM。结论表明,基于SOI技术,仅需进行器件结构和存储单元的适当考虑,即可达到较好的抗单粒子翻转能力。     

High performance fully-depleted tri-gate CMOS transistors

Fully-depleted (FD) tri-gate CMOS transistors with 60 nm physical gate lengths on SOI substrates have been fabricated. These devices consist of a top and two side gates on an insulating layer. The transistors show near-ideal subthreshold gradient and excellent DIBL behavior, and have drive current characteristics greater than any non-planar devices reported so far, for correctly-targeted threshold voltages. The tri-gate devices also demonstrate full depletion at silicon body dimensions approximately 1.5 - 2 times greater than either single gate SOI or non-planar double-gate SOI for similar gate lengths, indicating that these devices are easier to fabricate using the conventional fabrication tools. Comparing tri-gate transistors to conventional bulk CMOS device at the same technology node, these non-planar devices are found to be competitive with similarly-sized bulk CMOS transistors. Furthermore, three-dimensional (3-D) simulations of tri-gate transistors with transistor gate lengths down to 30 nm show that the 30 nm tri-gate device remains fully depleted, with near-ideal subthreshold swing and excellent short channel characteristics, suggesting that the tri-gate transistor could pose a viable alternative to bulk transistors in the near future.     

SOI/bulk hybrid technology on SIMOX wafers for high performancecircuits with good ESD immunity

A new SOI/bulk hybrid technology with devices on both the thin film and the bottom substrate of SIMOX wafers has been studied. By fabricating ESD protection circuits on the substrate of SIMOX wafers, ESD reliability of high performance CMOS SOI circuits can be significantly improved. Despite the higher surface defect density and micro-roughness on the bottom substrate of SIMOX wafers compared to ordinary bulk wafers, similar electron mobility, intrinsic thermal oxide properties and hot-carrier degradation are observed among MOSFET's fabricated on the different substrates. Thus, the hybrid technology is capable of combining the advantages both of SOI and bulk technology in fabricating high performance circuits     

SOI在射频电路中的应用

随着射频电路(RF)工作频率和集成度的提高,衬底材料对电路性能的影响越来越大.SOI(Silicon-on-Insulator)结构以其良好的电学性能,为系统设计提供了灵活性.与CMOS工艺的兼容使它能将数字电路与模拟电路混合,在射频电路应用方面显示巨大优势.文章分析了RF电路发展中遇到的挑战和SOI在RF电路中的应用优势,综述了SOI RF电路的最新进展.     

Integrated sensor and electronic circuits in fully depleted SOItechnology for high-temperature applications

The electrical characteristics of devices and circuits realized in CMOS technology on silicon-on-insulator (SOI) substrates and operated at elevated temperatures are presented and compared with results obtained using other materials (bulk Si, GaAs, SiC). It is demonstrated that fully depleted CMOS on SOI is the most suitable process for the realization of complex electronic circuits to be operated in high-temperature environments, up to more than 300°C     

A low voltage hybrid bulk/SOI CMOS active pixel image sensor

A hybrid bulk/silicon-on-insulator (SOI) complementary metal oxide semiconductor (CMOS) active pixel image sensor has been fabricated and studied. The active pixel comprised of reset and source follow transistors on the SOI thin film while the photodiode is fabricated on the SOI handling substrate after removing the buried oxide. The bulk photodiode can be optimized for efficiency with the use of lightly doped SOI substrate without compromising the circuit performance. On the other hand, the elimination of wells on the SOI thin-film allows the use of PMOSFET without increasing the pixel size. The addition of a PMOSFET in the active pixel structure can reduce the minimum operating voltage of the circuit beyond that of conventional designs. With the combination of the high quantum efficiency of bulk photodiode and the low power advantage of SOI technology, the hybrid technology is attractive for scaled low voltage imaging applications