CMOS／SOI电路模拟与参数提取

ＳＯＩ－ＭＯＳＦＥＴ主要模型参数得一致的提取，因而该模型嵌入ＳＰＩＣＥ后能保证ＣＭＯＳ／ＳＯＩ电路的正确模拟工作，从ＣＭＯＳ／ＳＯＩ器件和环振电路的模拟结果和实验结果看，两者符合得较好，说明我们所采用的ＳＯＩ ＭＯＳＦＥＴ器件模型及其参数提取都是成功的。     

pH—ISFET器件及其电路的SPICE模拟方法

本文提出了用ＳＰＩＣＥ软件模拟ｐＨ－ＩＳＦＥＴ器件及其电路的方法。通过ＳＰＩＣＥ内部的ＭＯＳＦＥＴ参数和引入一些信号源来实现对ｐＨ－ＩＳＦＥＴ传感器及其电路的ｐＨ灵敏度关系，瞬态响应以及温度特性的模拟，所得结果与实验观测结果基本相符。     

开关电流电路中的时钟馈入效应

本文采用ＭＯＳ开关的集总时变ＲＣ模型，对开关电流（ＳＩ）电路中的时钟馈入效应进行了详细的理论分析，导出了开关电流镜中钟馈电压和钟馈电流的表达式，从而揭示出了钟馈电压／电流与工艺参数、ＭＯＳ器件尺寸、时钟信号幅值及其下降沿斜率等之间的内在关系。用它可对ＳＩ电路中时钟馈入的影响进行快速预测。文中的理论分析与ＳＰＩＣＥ仿真结果相一致。所提供的结果对于设计高精度低功耗ＳＩ电路有应用价值。     

一种用于神经计算的竞争电路的设计

作为一种重要的神经元网络的竞争电路，以往的电路实现结构往往有电路复杂度大和相互联接过多的缺点，不利于ＶＬＳＩ实现。在ｒａｉｌ－ｔｏ－ｒａｉｌ放大器结构的基础上，提出了一咱新的ＣＭＯＳ电路实现方法，解决了这些问题。ＨＳＰＩＣＥ的模拟结果证明了设计的正确性。     

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。     

自对准硅化物CMOS／SOI技术研究

在ＣＭＯＳ／ＳＩＭＯＸＳＯＩ电路制作中引入了自对准钴（Ｃｏ）硅化物（ＳＡＬＩＣＩＤＥ）技术，研究了ＳＡＬＩＣＩＤＥ工艺对ＳＯＩＭＯＳＦＥＴ单管特性和ＣＭＯＳ／ＳＯＩ电路速度性能的影响．实验表明，采用ＳＡＬＩＣＩＤＥ技术能有效地减小ＭＯＳＦＥＴ栅、源、漏电极的寄生接触电阻和方块电阻，改善单管的输出特性，降低ＣＭＯＳ／ＳＯＩ环振电路门延迟时间，提高ＣＭＯＳ／ＳＯＩ电路的速度特性．     

自对准硅化物SOI／CMOS技术研究

在ＳＯＩ／ＣＭＯＳ电路制作中引入了自对准钴硅化物（ＳＡＬＩＣＩＤＥ）技术，研究了ＳＡＬＩＣＩＤＥ工艺对ＳＯＩ／ＭＯＳＦＥＴ单管特性和ＳＯＩ／ＣＭＯＳ电路速度性能的影响。实验表明，ＳＡＬＩＣＩＤＥ技术能有效地减小ＭＯＳＦＥＴ栅、源、漏电极的寄生接触电阻和薄层电阻，改善单管的输出特性，降低ＳＯＩ／ＣＭＯＳ环振电路门延迟时间，提高ＳＯＩ／ＣＭＯＳ电路的速度特性。     

一种12位开关电流型Σ-△调制器

开关电流电路（ＳＩ）是近年兴起的一种模拟电路。文中引用了新型的两步采样开关电流技术（Ｓ＾２Ｉ）,对该电路中减小时钟馈漏效应的几种方法进行了分析。利用差分平衡结构的Ｓ＾２Ｉ存储单元设计了平衡Ｓ＾２Ｉ积分器,并在此基础上设计出一种平衡差分结构的二阶∑－△调制器。该调制器能够完全与标准ＣＭＯＳ数字工艺兼容。利用标准１．２μｍ数字ＣＯＭＳ工艺的ＨＳＰＩＣＥ模型参数进行了分析,该电路信噪比达到７３．３ｄＢ,     

低通滤波器结构的改进分析及模拟

在高频域，ＭＯＳＦＥＴ的分布参数对全集成ＭＯＳＦＥＴ－Ｃ滤波器的特性有很大影响，本文应用ＳＰＩＣＥ（Ⅱ）通用模拟电路程序，采用非理想运算放大器单极点电路模型，考虑到ＭＯＳＦＥＴ的寄生电容，对一个六阶切比雪夫低通滤波器全ＭＯＳＦＥＴ－Ｃ平衡结构应用传输线模型进行了仿真分析。     

适合于PSPICE的一种精确的功率MOSFET等效电路

建立了一种新的功率ＭＯＳＦＥＴ等效电路，以便利用先进的电路模拟软件ＰＳＰＩＣＥ对功率ＭＯＳＦＥＴ所有特性进行模拟和分析．对ＩＲ公司的各类ＨＥＸＦＥＴ进行的模拟结果与其数据手册中的实验曲线十分吻合，表明该模型具有较高的精确性．     

Computer-aided performance assessment of fully depleted SOI CMOSVLSI circuits

A physical model for the fully depleted submicrometer SOI MOSFET is described and used to assess the performance of SOI CMOS VLSI digital circuits. The computer-aided analysis is focused on both problematic and beneficial effects of the parasitic bipolar junction transistor (BJT) in the floating-body device. The study shows that the bipolar problems overwhelm the benefits, and hence must be alleviated by controlling the activation of the BJT via device design tradeoffs. A feasible approach to the needed design optimization is demonstrated by veritable device/circuit simulations, which also predict significant speed superiority of SOI over bulk-silicon CMOS circuits in scaled, submicrometer technologies     

Vertically integrated SOI circuits for low-power and high-performance applications

Vertical integration offers numerous advantages over conventional structures. By stacking multiple-material layers to form double gate transistors and by stacking multiple device layers to form multidevice-layer integration, vertical integration can emerge as the technology of choice for low-power and high-performance integration. In this paper, we demonstrate that the vertical integration can achieve better circuit performance and power dissipation due to improved device characteristics and reduced interconnect complexity and delay. The structures of vertically integrated double gate (DG) silicon-on-insulator (SOI) devices and circuits, and corresponding multidevice-layer (3-D) SOI circuits are presented; a general double-gate SOI model is provided for the study of symmetric and asymmetric SOI CMOS circuits; circuit speed, power dissipation of double-gate dynamic threshold (DGDT) SOI circuits are investigated and compared to single gate (SG) SOI circuits; potential 3-D SOI circuits are laid out. Chip area, layout complexity, process cost, and impact on circuit performance are studied. Results show that DGDT SOI CMOS circuits provide the best power-delay product, which makes them very attractive for low-voltage low-power applications. Multidevice-layer integration achieves performance improvement by shortening the interconnects. Results indicate that up to 40% of interconnect performance improvements can be expected for a 4-device-layer integration.     

A physical charge-based model for non-fully depleted SOI MOSFET'sand its use in assessing floating-body effects in SOI CMOS circuits

A new model for the non-fully depleted (NFD) SOI MOSFET is developed and used to study floating-body effects in SOI CMOS circuits. The charge-based model is physical, yet compact and thus suitable for device/circuit simulation. Verified by numerical device simulations and test-device measurements, and implemented in (SOI)SPICE, it reliably predicts floating-body effects resulting from free-carrier charging in the NFD/SOI MOSFET, including the purportedly beneficial supra-ideal sub-threshold slope due to impact ionization and a saturation current enhancement due to thermal generation. SOISPICE CMOS circuit simulations reveal that the former effect is not beneficial and could be detrimental, but the latter effect can be beneficial, especially in low-voltage applications, when accompanied by a dynamic floating-body effect that effectively reduces static power. The dynamic floating-body effects are hysteretic, however, and hence exploitation of the beneficial ones will necessitate device/circuit design scrutiny aided by physical models such as the one presented herein     

Physical subthreshold MOSFET modeling applied to viable design ofdeep-submicrometer fully depleted SOI low-voltage CMOS technology

An insightful study of the subthreshold characteristics of deep-submicrometer fully depleted SOI MOSFET's, based on two-dimensional numerical (PISCES) device simulations, shows that the gate swing and off-state current are governed by gate bias-dependent source/drain charge sharing, which controls back-channel as well as front-channel conduction. The insight from this study guides the development of a physical, two-dimensional analytic model for the subthreshold current and charge, which is linked to our strong-inversion formalism in SOISPICE for circuit simulation. The model is verified by PISCES simulations of scaled devices. The utility of the model in SOISPICE is demonstrated by using it to define a viable design for deep-submicrometer fully depleted SOI CMOS technology based on simulated speed and static power in low-voltage digital circuits     

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     

0.5μm SOI CMOS器件和电路

研究了0.5μm SOI CMOS器件和电路,开发出成套的0.5μm SOI CMOS工艺.经过工艺投片,获得了性能良好的器件和电路,其中当工作电压为3V时,0.5μm 101级环振单级延迟为42ps.同时,对部分耗尽SOI器件特性,如“浮体”效应、“kink”效应和反常亚阈值特性进行了讨论.     

抗辐照SOI256kB只读存储器的ESD设计

ESD设计技术已成为业界提升SOI电路可靠性的一个瓶颈技术。文章介绍了一款具有抗辐照能力、基于SOI／CMOS工艺技术研制的容量为256kB只读存储器电路的ESD设计方案。结合电路特点详细分析了其ESD设计的难点,阐述了从工艺、器件和电路三个方面如何密切配合,进行SOI电路ESD设计的分析思路和解决方法。电路基于0．8...     

SiGe沟道SOI CMOS的设计及模拟

在 SOI(Silicon on Insulator)结构硅膜上面生长一层 Si Ge合金 ,采用类似 SOICMOS工艺制作成具有Si Ge沟道的 SOICMOS集成电路。该电路不仅具有 SOICMOS电路的优点 ,而且因为 Si Ge中的载流子迁移率明显高于 Si中载流子的迁移率 ,所以提高了电路的速度和驱动能力。另外由于两种极性的 SOI MOSFET都采用 Si Ge沟道 ,就避免了只有 SOIPMOSFET采用 Si Ge沟道带来的选择性生长 Si Ge层的麻烦。采用二维工艺模拟得到了器件的结构 ,并以此结构参数进行了器件模拟。模拟结果表明 ,N沟和 P沟两种 MOSFET的驱动电流都有所增加 ,PMOSFET增加得更多一些     

Optimal asymmetrical back plane biasing for energy efficient digital circuits in 28 nm UTBB FD-SOI

In this work we propose an optimal back plane biasing (OBB) scheme to be used in a UTBB FD SOI technology that minimizes the energy per operation consumption of sub threshold digital CMOS circuits. By using this OBB scheme, simulations show that more than 30% energy savings can be obtained with low threshold voltage (LVT) devices in comparison with classic symmetric back plane biasing (SBB) schemes. Additionally, this OBB scheme allows to adjust the performance of the circuit with very small energy penalties. A very simple and intuitive model, for sub threshold digital CMOS circuits, was developed to justify the benefits obtained by OBB. The results predicted by the model are confirmed with extensive simulation results. We show that the OBB approach can be applied easily to a given circuit just based on the information provided by a logic simulation of the circuit (or even an analysis of its structure) and simple electrical simulations of the pMOS and nMOS transistors. Finally, we show that the variability in the energy consumption is improved by using OBB and suggests that new sizing methodologies must be studied to fully benefit from the wide back plane voltage range available in UTBB FD SOI technology for the design of robust energy efficient digital circuits.     

Novel high speed circuit structures for BiCMOS environment

Novel high speed BiCMOS circuits including ECL/CMOS, CMOS/ECL interface circuits and a BiCMOS sense amplifier are presented. A generic 0.8 μm complementary BiCMOS technology has been used in the circuit design. Circuit simulations show superior performance of the novel circuits over conventional designs. The time delays of the proposed ECL/CMOS interface circuits, the dynamic reference voltage CMOS/ECL interface circuit and the BiCMOS sense amplifier are improved by 20, 250, and 60%, respectively. All the proposed circuits maintain speed advantage until the supply voltage is scaled down to 3.3 V