阈算术代数系统及多值电流型CMOS电路设计

该文根据电流信号易于实现算术运算的特点,定义了阈算术运算及非负运算,建立了一个适合于电流型电路设计的阈算术代数系统,并在阈算术代数系统中定义和图为阈算术函数的图形表示。在此基础上,通过三值电流型CMOS电路的设计实例,阐述了运用和图将逻辑函数转化为阈算术函数的电流型CMOS电路设计方法。采用TSMC 0.18m CMOS工艺参数的HSPICE模拟结果表明,所设计的电路具有正确的逻辑功能。阈算术代数系统的提出及和图的运用为电流型电路设计提供了一种新的简单有效的方法。     

三值双传输管电路的通用综合方法

提出采用双传管逻辑设计三值电路的方法,对每个MOS管的逻辑功能均采用传输运算予以表示以实现有效综合.建立了三值双传输管电路的反演法则和对偶法则.新提出的三值双传输管逻辑电路具有完全基于标准CMOS工艺,无需对MOS管作任何阈值调整,结构简单、规则,输入信号负载对称性好,逻辑摆幅完整以及无直流功耗等特点.采用TSMC 0.25μm工艺参数和最高电压为3V的HSPICE模拟结果验证了所提出综合方法的正确性.     

Single event crosstalk prediction in nanometer technologies

As CMOS technology continues to scale down, circuits become increasingly more sensitive to transient pulses caused by single event (SE) particles. On the other hand, coupling effects among interconnects can cause single event transients to contaminate electronically unrelated circuit paths which may increase the SE susceptibility of CMOS circuits. The coupling effects among interconnects need to be considered in single event hardening, modeling and analysis of CMOS logic gates due to technology scaling effects that increase both SE vulnerability and crosstalk effects. This work, for the first time, proposes an SE crosstalk noise estimation method for use in design automation tools. The proposed method uses an accurate 4-π model for interconnect and correctly models the effect of non-switching aggressors as well as aggressor tree branches noting the resistive shielding effect. The SE crosstalk noise expressions derived show very good results in comparison to HSPICE results. Results show that average error for noise peak is about 5.2% while allowing for very fast analysis in comparison to HSPICE.     

Modeling single event crosstalk speedup in nanometer technologies

With advances in CMOS technology, circuits become increasingly more sensitive to transient pulses caused by single event (SE) particles. In addition, coupling effects among interconnects can cause SE transients to spread electronically unrelated circuit paths which may increase the SE Susceptibility of CMOS circuits. The coupling effects among interconnects need to be considered in single event modeling and analysis of CMOS logic gates due to technology scaling effects that increase both SE vulnerability and crosstalk effects. This work reports on the signal speedup effects caused by SE crosstalk and then proposes a best-case delay estimation methodology for use in design automation tools for the first time to our knowledge. The SE coupling speedup expressions derived show very good results in comparison to HSPICE results. Results show an average error of about 8.42% for best-case delay while allowing for very fast analysis in comparison to HSPICE.     

MOS current mode circuits: analysis, design, and variability

The interest in MOS current-mode logic (MCML) is increasing because of its ability to dissipate less power than conventional CMOS circuits at high frequencies, while providing an analog friendly environment. Moreover, automated design methodologies are gaining attention by circuit designers to provide shorter design cycles and faster time to market. This paper provides designers with an insight to the different tradeoffs involved in the design of MCML circuits to efficiently and systematically design MCML circuits. A comprehensive analytical formulation for the design parameters of MCML circuits using the BSIM3v3 model is introduced. In addition, a closed-form expression for the noise margin of two-level MCML circuits is derived. In order to verify the validity of the analytical formulations, an automated design methodology for MCML circuits is proposed to overcome the complexities of the design process. The effectiveness of the design methodology and the accuracy of the analytical formulations are tested by designing several MCML benchmarks built in a 0.18-/spl mu/m CMOS technology. The error in the required performance in the designed circuits is within 11% when compared to HSPICE simulations. A worst case parameter variations modeling is presented to investigate the impact of variations on MCML circuits as well as designing MCML circuits for variability. Finally, the impact of variations on MCML circuits is investigated with technology scaling and different circuit architectures.     

A 1.5-V differential cross-coupled bootstrapped BiCMOS logic forlow-voltage applications

Two new bipolar complementary metal-oxide-semiconductor (BiCMOS) differential logic circuits called differential cross-coupled bootstrapped BiCMOS (DC²B-BiCMOS) and differential cross-coupled BiCMOS (DC²-BiCMOS) logic are proposed and analyzed. In the proposed two new logic circuits, the novel cross-coupled BiCMOS buffer circuit structure is used to achieve high-speed operation under low supply voltage. Moreover, a new bootstrapping technique that uses only one bootstrapping capacitor is adopted in the proposed DC²B-BiCMOS logic to achieve fast near-full-swing operation at 1.5 V supply voltage for two differential outputs. HSPICE simulation results have shown that the new DC²B-BiCMOS at 1.5 V and the new DC²-BiCMOS logic at 2 V have better speed performance than that of CMOS and other BiCMOS differential logic gates. It has been verified by the measurement results on an experimental chip of three-input DC²B-BiCMOS XOR/XNOR gate chain fabricated by 0.8 μm BiCMOS technology that the speed of DC²-BiCMOS at 1.5 V is about 1.8 times of that of the CMOS logic at 1.5 V. Due to the excellent circuit performance in high-speed, low-voltage operation, the proposed DC²B-BiCMOS and DC²-BiCMOS logic circuits are feasible for low-voltage, high-speed applications     

A CMOS Analog Cell and its applications in analog signal processing

This paper presents a core cell that can be reconfigured and combined with current mirrors to implement exponential, logarithmic, multiplier, divider and raise-to-power function circuits. The proposed circuit uses CMOS transistors operating in the strong inversion. The proposed circuits has been verified with the 0.8?µm CMOS technology by HSPICE simulations. The simulations results confirm the functionality of the proposed circuits. The proposed circuits paves the way for designing analog signal processors.     

采用多输入浮栅MOS器件的四值编-译码电路设计

提出一种采用多输入浮栅MOS管设计具有可控阈值功能的电压型多值逻辑电路的方法.对每个浮栅MOS管的逻辑功能均采用传输开关运算予以表示以实现有效综合。在此基础上提出了一种新的电压型多输入浮栅MOS四值编码器和译码器设计。所提出的电路在结构上得到了非常明显的简化,并可采用标准的双层多晶硅CMOS工艺予以实现。此外,这些电路具有逻辑摆幅完整、延迟小等特点。采用TSMC0.35μm双层多晶硅CMOS工艺参数的HSPICE模拟结果验证了所提出设计方案的正确性。     

Circuit implementation of high-resolution rational-powered membership functions in standard CMOS technology

This paper proposes the method to implement a general form of membership functions for fuzzy systems in CMOS technology. These membership functions are a general form of triangular types and those functions which are used in linguistic hedge fuzzy logic, hence can offer better performance in almost all applications. The comparison between the proposed method and previously reported works shows better performance in all parameters. Designed circuits to implement these types of membership functions are simulated using HSPICE by level 49 parameters (BSIM3v3) in 0.35 μm standard CMOS technology. Current mode realization of the circuits leads to simple and intuitive configurations. The Rational Power Generator Module (RPGM) generates powers with the resolution of 0.03125 and using seven programming bits. The simulation results of RPGM demonstrate a RMS error of 1.42% and a maximum power consumption of 1.05 mW.     

PVT variations aware low leakage INDEP approach for nanoscale CMOS circuits

Increasing in device parameter variations is the critical issue in very deep sub-micron regime due to continue scaling of the transistor dimensions. The overall performance yield of the logic circuit is diminished by raising leakage current and variability issues in scaled devices. In this article; we have proposed an approach called INDEP, based on Boolean logic calculation for the input signals of the extra inserted transistors between the pull-up and pull-down network of the CMOS logic. INDEP approach is not only reduces the leakage current but also mitigates the variability issues with minimum susceptible delay paths. Various process, voltage and temperature (PVT) variations are analyzed at 22 nm BSIM4 bulk CMOS PTM technology node for chain of 5-inverters using HSPICE tool. Several guidelines are provided to design the variability aware CMOS circuits in nanoscale regime by considering the leakage current variation. INDEP approach works effectively in both active as well as standby state of the circuit and keeping the modal performance characteristics of the CMOS gate. The electrical simulation results show that our proposed INDEP approach is less susceptible to PVT variations as compared to conventional circuit. The Monte-Carlo simulation results confirm that average INDEP leakage current reduction is 62.31% at ±20% PVT variations under 3σ Gaussian distribution for chain of 5-inverters.     

A new and efficient approach for estimating the accurate time-domain response of single and capacitive coupled distributed RC interconnects

This paper describes a novel yet highly efficient approach for estimating the time-domain response of capacitive coupled distributed RC interconnects. By using this method, the voltage signal at any particular point in such wires can be accurately and quickly obtained with very low computational cost. The proposed model exhibits a very good agreement with HSPICE simulations with worst-case error less than 3% and can be readily implemented in CAD analysis tools. This paper also presents an efficient model to estimate the capacitive crosstalk in high-speed very large scale integration (VLSI) circuits. Experimental results show that the maximum error of our peak noise predictions is less than 2.5%. In addition, this work presents an efficient artificial neural network (ANN)-based technique for modeling the time-domain response of interconnects and crosstalk noise. While existing fast noise estimation metrics may overestimate or underestimate the coupling noise, the simulation results demonstrate the ability of this approach to successfully predict coupling noise with a very good accuracy as compared to HSPICE in modest CPU times. Thereby, the proposed models and techniques can be used to predict the signal integrity for designing high-speed and high-density VLSI circuits.     

新型低噪声电流型CMOS边沿触发器设计

提出以电流信号表示逻辑值的新型低噪声触发器设计,用于高性能混合集成电路的设计中以减少存贮单元开关噪声对模拟电路性能的影响。所提出的设计包括主从型边沿触发器和单闩锁单边沿触发器。单个锁存器的电流型边沿触发器设计是通过在有效时钟沿后产生的窄脉冲使锁存器瞬时导通完成一次取样求值。与主从型触发器相比,单闩锁结构的触发器具有结构简单、直流功耗低的特点。采用0.25μm CM O S工艺参数的HSP ICE模拟结果表明,所提出的电流型触发器工作时,在电源端产生的电流波动远远小于传统的CM O S电路。     

A new true-single-phase-clocking BiCMOS dynamic pipelined logicfamily for high-speed, low-voltage pipelined system applications

New true-single-phase-clocking (TSPC) BiCMOS/BiNMOS/BiPMOS dynamic logic circuits and BiCMOS/BiNMOS dynamic latch logic circuits for high-speed dynamic pipelined system applications are proposed and analyzed. In the proposed circuits, the bootstrapping technique is utilized to achieve fast near-full-swing operation. The circuit performance of the proposed new dynamic logic circuits and dynamic latch logic circuits in both domino and pipelined applications are simulated by using HSPICE with 1 μm BiCMOS technology. Simulation results have shown that the new dynamic logic circuits and dynamic latch logic circuits in both domino and pipelined applications have better speed performance than that of CMOS and other BiCMOS dynamic logic circuits as the supply voltage is scaled down to 2 V. The operating frequency and power dissipation/MHz of the pipelined system, which is constructed by the new clock-high-evaluate-BiCMOS dynamic latch logic circuit and clock-low-evaluate-BiCMOS (BiNMOS) dynamic latch logic circuit, and the logic units with two stacked MOS transistors, are about 2.36 (2.2) times and 1.15 (1.1) times those of the CMOS TSPC dynamic logic under 1.5-pF output loading at 2 V, respectively. Moreover, the chip area of these two BiCMOS pipelined systems is about 1.9 times and 1.7 times as compared with that of the CMOS TSPC pipelined system. A two-input dynamic AND gate fabricated with 1 μm BiCMOS technology verifies the speed advantage of the new BiNMOS dynamic logic circuit. Due to the excellent circuit performance in high-speed, low-voltage operation, the proposed new dynamic logic circuits and dynamic latch logic circuits are feasible for high-speed, low-voltage dynamic pipelined system applications     

A Novel Design Approach for Ternary Compressor Cells Based on CNTFETs

Using multiple-valued logic provides more information transmission over a signal line. So it could solve the binary logic circuits problems such as interconnections requirement. In this paper, a universal method for designing ternary 3-2 and 4-2 compressor cells based on carbon nanotube field-effect transistors (CNTFETs) is presented. The proposed circuits use unique properties of CNTFETs, such as adjustable threshold voltage by changing CNT diameter and ballistic carrier transportation. In both designs transmission gates, ternary decoder and standard ternary buffers with different threshold voltages are used. The proposed compressors receive three (for 3-2 compressor) or four (for 4-2 compressor) ternary digits, produce the summation of these digits and show the results in two ternary digits (Sum, Carry). For evaluation and simulation the proposed circuits, Synopsys HSPICE simulator with 32 nm compact model is used in different simulation conditions.     

Exploring the design space of mixed swing quadrail for low-powerdigital circuits

This paper describes and explores the design space of a mixed voltage swing methodology for lowering the energy per switching operation of digital circuits in standard submicron complementary metal-oxide-semiconductor (CMOS) fabrication processes. Employing mixed voltage swings expands the degrees of freedom available in the power-delay optimization space of static CMOS circuits. In order to study this design space and evaluate the power-delay tradeoffs, analytical polynomial formulations for power and delay of mixed swing circuits are derived and HSPICE simulation results are presented to demonstrate their accuracy. Efficient voltage scaling and transistor sizing techniques based on our analytical formulations are proposed for optimizing energy/operation subject to target delay constraints; up to 2.2× improvement in energy/operation is demonstrated for an ISCAS'85 benchmark circuit using these techniques. Experimental results from HSPICE simulations and measurements from an And-Or-Invert (AO1222) test chip fabricated in the Hewlett-Packard 0.5 μm process are presented to demonstrate up to 2,92× energy/operation savings for optimized mixed swing circuits compared to static CMOS     

基于共振隧穿二极管的阈值逻辑单元电路设计

共振隧穿二极管作为较为成熟的纳米电子器件,已被广泛应用于高速低功耗电路。由于其具有负内阻特性,单一门电路的功能大大增加,减少了电路的复杂度。在阈值逻辑函数的硬件实现方面,共振隧穿器件也体现出显著的优势。结合谱技术,基于共振隧穿二极管,设计了可实现任意三变量阈值逻辑函数的阈值逻辑单元电路。该电路还可作为阈值逻辑网络中的基本单元,实现复杂的逻辑功能。通过HSPICE软件,仿真验证了所设计电路的正确性。     

Design and Evaluation of CNFET-Based Quaternary Circuits

This paper presents novel high-performance and PVT tolerant quaternary logic circuits as well as efficient quaternary arithmetic circuits for nanoelectronics. These Carbon Nanotube FET (CNFET)-based circuits are compatible with the recent technologies and are designed based on the conventional CMOS architecture, while the previous quaternary designs used methods which are not suitable for nanoelectronics and have become obsolete. The proposed designs are robust and have large noise margins and high driving capability. The singular characteristics of CNFETs, such as the capability of having the desired threshold voltage by regulating the diameters of the nanotubes, make them very appropriate for voltage-mode multiple-threshold circuits design. The proposed circuits are examined, using Synopsys HSPICE with the standard 32?nm-CNFET technology in various situations and different supply voltages. Simulation results demonstrate the correct and high-performance operation of the proposed circuits even in the presence of process, voltage and temperature variations.     

Fast solution of nonlinear equations using parallel analog hardware

Parallel analog circuits are introduced for the solution of systems of nonlinear algebraic equations and the integration of systems of differential equations. Both simulations using HSPICE and a hardware implementation are presented which show how the circuitry can be used to solve: the power flow and transient analysis problems for power systems, and the simulation of a jet engine. In all cases solutions are obtained in better than real time. The results are comparable in accuracy to digital solutions of the same problems.     

An Efficient 5‐Input Exclusive‐OR Circuit Based on Carbon Nanotube FETs

The integration of digital circuits has a tight relation with the scaling down of silicon technology. The continuous scaling down of the feature size of CMOS devices enters the nanoscale, which results in such destructive effects as short channel effects. Consequently, efforts to replace silicon technology with efficient substitutes have been made. The carbon nanotube field‐effect transistor (CNTFET) is one of the most promising replacements for this purpose because of its essential characteristics. Various digital CNTFET‐based circuits, such as standard logic cells, have been designed and the results demonstrate improvements in the delay and energy consumption of these circuits. In this paper, a new CNTFET‐based 5‐input XOR gate based on a novel design method is proposed and simulated using the HSPICE tool based on the compact SPICE model for the CNTFET at the 32‐nm technology node. The proposed method leads to improvements in performance and device count compared to the conventional CMOS‐style design.     

Design of ternary CMOS circuits based on transmission function theory

This paper presents threshold comparison operation, transmission operation and union operation which can be used to describe the function of MOS transistors in a pass-transistor network. The relative properties and circuit realizations of these operations, and the transmission function expression by use of these operations are discussed. A transmission function theory suitable to CMOS network synthesis is proposed. This paper also discusses the simplification of ternary functions and proposes minimized design of some basic ternary CMOS circuits. The computer simulation using SPICE2G5 has confirmed that these circuits have desirable DC transfer characteristics.