SPICE model of trench-gate MOSFET device

A novel simulation program with an integrated circuit emphasis（SPICE） model developed for trench-gate metal-oxide-semiconductor field-effect transistor（M OSFET）devices is proposed. The drift region resistance was modeled according to the physical characteristics and the specific structure of the trench-gate MOSFET device. For the accurate simulation of dynamic characteristics, three important capacitances, gate-to-drain capacitance Cgd, gate-to-source capacitance Cgsand drain-to-source capacitance Cds, were modeled, respectively, in the proposed model. Furthermore,the self-heating effect, temperature effect and breakdown characteristic were taken into account; the self-heating model and breakdown model were built in the proposed model; and the temperature parameters of the model were revised. The proposed model is verified by experimental results, and the errors between measured data and simulation results of the novel model are less than 5%. Therefore, the model can give an accurate description for both the static and dynamic characteristics of the trench-gate MOSFET device.

The influences of model parameters on the characteristics of memristors

As the fourth passive circuit component, a memristor is a nonlinear resistor that can ＂remember＂ the amount of charge passing through it. The characteristic of ＂remembering＂ the charge and non-volatility makes memristors great potential candidates in many fields. Nowadays, only a few groups have the ability to fabricate memristors, and most researchers study them by theoretic analysis and simulation. In this paper, we first analyse the theoretical base and characteristics of memristors, then use a simulation program with integrated circuit emphasis as our tool to simulate the theoretical model of memristors and change the parameters in the model to see the influence of each parameter on the characteristics. Our work supplies researchers engaged in memristor-based circuits with advice on how to choose the proper parameters.

Characteristics of titanium oxide memristor with coexistence of dopant drift and a tunnel barrier

The recent published experimental data of titanium oxide memristor devices which are tested under the same experi- mental conditions exhibit the strange instability and complexity of these devices. Such undesired characteristics preclude the understanding of the device conductive processes and the memristor-based practical applications. The possibility of the coexistence of dopant drift and tunnel barrier conduction in a memristor provides preliminary explanations for the undesired characteristics. However, current research lacks detailed discussion about the coexistence case. In this paper, dopant drift and tunnel barrier-based theories are first analyzed for studying the relations between parameters and physical variables which affect characteristics of mernristors, and then the influences of each parameter change on the conductive behaviors in the single and coexistence cases of the two mechanisms are simulated and discussed respectively. The simulation results provide further explanations of the complex device conduction. Theoretical methods of eliminating or reducing the coex- istence of the two mechanisms are proposed, in order to increase the stability of the device conduction. This work also provides the support for optimizing the fabrications of memristor devices with excellent performance.

Design of Multi-Valued Logic Circuit Using Carbon Nano Tube Field Transistors

The design of a three-input logic circuit using carbon nanotube field effect transistors(CNTFETs)is presented.Ternary logic must be an exact replacement for dual logic since it performs straightforwardly in digital devices,which is why this design is so popular,and it also reduces chip area,both of which are examples of circuit overheads.The proposed module we have investigated is a triple-logic-based one,based on advanced technology CNTFETs and an emphasis on minimizing delay times at various values,as well as comparisons of the design working with various load capacitances.Comparing the proposed design with the existing design,the delay times was reduced from 66.32 to 16.41 ps,i.e.,a 75.26%reduction.However,the power dissipation was not optimized,and increased by 1.44%compared to the existing adder.The number of transistors was also reduced,and the product of power and delay(P∗D)achieved a value of 0.0498053 fJ.An improvement at 1 V was also achieved.A load capacitance(fF)was measured at different values,and the average delay measured for different values of capacitance had a maximum of 83.60 ps and a minimum of 22.54 ps,with a range of 61.06 ps.The power dissipations ranged from a minimum of 3.38μW to a maximum of 6.49μW.Based on these results,the use of this CNTFET half-adder design in multiple Boolean circuits will be a useful addition to circuit design.

二极管器件SPICE电路模型对锥形离子通道I-V特性曲线的模拟

离子整流性是纳米离子通道的一个重要特征,具有整流性的离子通道体系也被称为纳米流体二极管.本文比较了离子通道的泊松-能斯特-普朗克(PNP)方程组模型和固体半导体的扩散-漂移模型,提出可以使用二极管器件的仿真电路模拟器(SPICE)电路模型对离子通道体系的电流-电压(I-V)曲线进行模拟.以锥形离子通道的PNP数值模型的计算结果为基础,通过对这一体系进行讨论,给出一个锥形离子通道的SPICE电路模型,它可以较好地模拟I-V特性曲线.离子通道SPICE电路模型的建立可用于研究纳米流体二极管作为一个器件在电路中的应用.

基于PSPICE建模仿真方法研究传输线网络时域响应

为研究注入式电磁脉冲对端接负载的传输线网络的耦合规律,以典型的环形网络和树形网络为研究对象,基于PSPICE建模仿真方法,研究方波脉冲在传输线网络中的时域响应.对端接电阻负载的同轴线网络瞬态响应的实验结果、BLT方程求解结果、PSPICE仿真结果进行了对比分析,表明了PSPICE方法与BLT方程求解结果及实验结果具有很好的一致性.针对BLT方程方法在求解电容、电感负载及非线性负载上存在计算复杂、较难求解的问题,利用PSPICE建模仿真方法对端接电容负载的环形同轴线网络、端接瞬态抑制二极管的树形同轴线网络和多芯线缆网络的方波脉冲瞬态响应进行了仿真,与实验结果具有较好的一致性.这些结果验证了PSPICE建模仿真方法在解决电磁脉冲对端接线性、频变及非线性负载的传输线网络时域响应的有效性.

基于改进的电流传送器的模拟乘法器设计

为优化四象限模拟乘法器的电路性能,以满足现代模拟信号处理电路高频低噪的应用要求,提出了一种新型低压四象限模拟乘法器。该乘法器以基于改进的电流传送器(MDDCC:Modified Differential Difference Current Conveyor)的模拟平方器为基本电路,采用台湾积体电路制造公司的0.18μm CMOS工艺的PSPICE(Personal Simulation Program with Integrated Circuit Emphasis)计算机软件进行仿真。仿真结果表明,该四象限乘法器具有良好线性,输入电压的范围为-0.1 V^+0.1 V,截止频率为451.307 MHz,当输入电压峰值为100 mV时,输出噪声电压小于150 nV。与已有乘法器比较,该乘法器电路具有较好的线性特性以及较高的截止频率和带宽,输出噪声电压有所减少,在高频信号处理系统中性能更优。

TSV结构的几种SPICE模型仿真

硅通孔(TSV)结构是2.5D/3D系统级封装(SiP)的关键电学互连单元,对TSV结构的准确建模是保证电学仿真精确程度的重要因素。基于传输线理论,对TSV结构进行了电气描述,提取结构中集总参数元件,并针对这些集总参数元件进行组合,得到几种不同的SPICE模型。对上述SPICE模型进行S参数仿真,作为比较,建立TSV结构的全波模型并通过有限元方法计算得到S参数。仿真结果表明,TSV结构主体主导了整个TSV结构的电性能,当信号频率在10 GHz以下时,由各个SPICE模型仿真得到的S参数和由有限元方法计算所得结果差别较小。对SPICE模型中的TSV与硅衬底间电容C TSV不同的处理方式对仿真结果影响明显。

基于断言的模拟矢量自动生成方法

VLSI模拟验证的一个关键问题是需要大量的模拟矢量来验证各种可能情况下设计的正确性.采用断言作为模拟验证的功能模型,提出和实现了一种基于断言的模拟矢量自动生成方法.针对要触发的断言,首先对设计进行化简,通过决策图模型将初始输入传播到断言,并将传播过程和断言条件一起转化成CLP约束,最后求解CLP约束生成模拟矢量.该方法的优势在于运用了字级(word-level)约束求解技术,能统一处理控制电路和数据通路间的数据传播,求解效率高;基于功能模型的模拟矢量生成技术,模拟矢量生成目标更明确;与动态加速技术相结合,使搜索过程效率更高;设计化简技术的运用使搜索过程计算复杂度只与断言有关.实验结果表明,该方法能快速找到并定位设计中的错误,生成模拟矢量效率更高.

氧化钒热敏薄膜非致冷红外探测器的等效模型

建立了氧化钒热敏薄膜微测辐射热计的PSPICE模型，结合一个具体的CMOS读出电路给出探测器的等效电路模型，分析了探测器的电学和噪声特性，根据等效模型基于微测辐射热计电阻Ro和读出电路MOS沟道宽度2个设计参数对噪声等效温差（NETD）进行了优化，优化数据表明：参数Ro取值为2～11kΩ，W取值为0、1～1．0μm时，得到的NETD值为0、1334～0．1885K。

基于UML的模拟电路仿真系统的设计

模拟电路仿真程序对集成电路设计和电路性能评价具有十分重要的意义。近年来,面向对象技术已成为软件设计的主流思想,以电路仿真系统为背景,给出了一种基于UML的面向对象的分析与设计方法,清楚有效地进行系统建模。这种方法在模拟电路仿真系统SPICE的开发过程中被证明是提高软件开发质量和效率的有效途径。

基于PSPICE6.3的电路仿真分析

介绍了 PSPICE 6.3的运行环境 ,仿真分析功能。

基于表面势的增强型p-GaN HEMT器件模型

为了满足功率电路及系统设计对p-GaN HEMT(High Electron Mobility Transistor)器件模型的需求,本文建立了一套基于表面势计算方法的增强型p-GaN HEMT器件SPICE(Simulation Program with Integrated Circuit Emphasis)模型.根据耗尽型GaN HEMT器件和增强型p-GaN HEMT器件结构的对比,推导出p-GaN栅结构电压解析公式.考虑到p-GaN栅掺杂效应和物理机理,推导出栅电容和栅电流解析公式.同时,与基于表面势的高电子迁移率晶体管高级SPICE模型内核相结合,建立完整的增强型p-GaN HEMT功率器件的SPICE模型.将所建立的SPICE模型与实测结果进行对比验证.结果表明,所建立的模型准确实现了包括转移特性、输出特性、栅电容以及栅电流在内的p-GaN HEMT器件的电学特性.模型仿真数据与实测数据拟合度误差均小于5%.本文所提出的增强型p-GaN HEMT器件模型在进行电路设计时具有重要的应用价值.

CMOS离子敏场效应管SPICE模型

完全用CMOS工艺实现离子敏场效应型晶体管(ISFET)成为可能,这种ISFET的栅极结构是由绝缘体、多晶硅、金属层叠起来,称之为多层栅结构。从ISFET的传感机理出发,通过分析金属氧化物场效应晶体管(MOSFET)阈值电压的原理,利用通用电路模拟程序(SPICE)建立了这种多层栅结构ISFET的物理模型,并对其静态输入输出特性进行仿真,仿真结果和试验数据基本相符。

功率VDMOS器件的新型SPICE模型

为解决垂直双扩散金属氧化物半导体(VDMOS器件)模型精确度差的问题,建立了一套新的VDMOS模型.与其他模型相比,该模型在VDMOS器件源极、漏极、栅极3个外部节点的基础上,又增加了4个内部节点,从而将VDMOS器件视为1个N沟道金属氧化物半导体(NMOS)与4个电阻的串联.采用表面势建模的原理计算了积累区的电阻,并对寄生结型场效应晶体管(JFET)耗尽及夹断2种状态进行分析,计算出寄生JFET区的电阻.分别考虑VDMOS器件外延层区与衬底区的电流路径,建立了这2个区域的电阻模型.模型仿真值与器件测试值的比较结果表明,该模型能够准确拟合VDMOS器件线性区、饱和区及准饱和区的电学特性.

一种基于小波分析和神经网络的模拟电路故障诊断的方法研究

提出了一种基于小波分析和神经网络的电路故障诊断方法。首先用PSPICE(Simulation Program with Integrated Circuit Emphasis,即集成电路编程仿真技术)电路仿真软件对电路进行仿真;然后对电路的输出节点电压信号进行小波分解,提取各频段的能量作为故障样本;最后利用神经网络的并行处理结构和非线性映射能力,实现故障诊断。仿真实验结果表明该方法对容差模拟电路故障定位具有较高的准确率,为模拟电路故障诊断技术开辟了一条道路,为模拟电路故障诊断技术开辟了一条道路。

基于场路仿真的PCIe电磁干扰分析及优化设计

采用电磁仿真技术,提前评估PCB的电磁兼容设计是否合理,当对PCB进行电磁兼容测试时,减少其电磁干扰不满足GMW 3097标准的情况出现。首先对PCB进行3D电磁场仿真,再与高速串行计算机扩展总线标准模块内芯片的通用模拟电路仿真模型的电路仿真动态链接,进行场路协同仿真。实验验证表明,该仿真方法的精度在6 dBμV之内,满足PCB加工工艺的误差和实验测试的不确定度,符合仿真精度要求。通过该仿真方法评估PCB的电磁干扰强度以及优化PCB的设计,将高速串行计算机扩展总线标准模块上的33Ω电阻替换为磁珠后,该PCB在1.6 GHz处的电磁干扰强度降低了13.4 dB。根据CISPR 25标准规定的1-m法进行测试,PCB的电磁干扰变为-3.4 dBμV,低于GMW 3097标准要求,从而验证了该措施的有效性。

包含SiC/SiO2界面电荷的SiC MOSFET的SPICE模型

建立碳化硅(silicon carbide,SiC)金属–氧化物–半导体场效应晶体管(metal-oxide-semiconductorfield-effect transistor, MOSFET)的通用模拟电路仿真器(simulation program with integrated circuit emphasis,SPICE)模型。模型采用三段电流表达式分别描述SiC MOSFET工作在截止区、线性区和饱和区,引入SiCMOSFET的漏极和源极之间的泄漏电流及栅极氧化层的泄漏电流,并采用包含SiC/SiO2界面电荷的迁移率模型描述沟道载流子在不同温度范围内的行为表现,建立电–热网络模型模拟SiC MOSFET在开关状态和高电应力下的自热效应。开关电路和短路实验验证了所建立的SiC MOSFET的SPICE模型的准确性。应用所建立的SPICE模型讨论不同密度的SiC/SiO2界面电荷对SiC MOSFET的开关特性及短路失效的影响。结果表明,高密度的界面电荷一方面能够延迟SiCMOSFET的导通并增加通态电阻,导致SiCMOSFET的开关损耗增加,另一方面能够降低SiCMOSFET在短路环境下的饱和电流,并延迟SiC MOSFET的失效。

光敏电阻的SPICE瞬态分析子电路模型

研究了一种应用ＳＰＩＣＥ（集成电路通用模拟程序）现有元器件条件，模拟含有时变器件电路的技巧。应用多项式逼近光敏电阻随发光强度变化曲线，将其转换为光敏电阻随时间变化曲线，结合受控电压源，产生ＳＰＩＣＥ程序描述的光敏电阻子电路模型。该方法可实现对含有时变电阻电路的ＳＰＩＣＥ瞬态分析。分析结果表明，光敏继电器开关电路的输出电压曲线与实际要求相吻合。这一方法同样适用于分析含有随时间、发光强度、温度等物理量连续变化的非线性电容电感元件电路。

电路系统常用数学方程的SPICE宏模型

利用ＳＰＩＣＥ（集成电路通用模拟程序）的多项式受控源可以实现多种复杂的非线性数学方程。本文给出了均方根值和绝对值的ＳＰＩＣＥ宏模型，将由几个受控源及电容、二极管简单模型构成的宏模型插入电路系统中，代替一级复杂的电路或一个功能模块，从而可提高分析精度，减少分析时间，克服不收敛问题，简化程序设计。这种宏模型也可以作为验证电路功能的一种手段，特别是在电路需要多次调用这一功能模块时，更显示出其优越性。