DESIGN OF TERNARY COUNTER BASED ON ADIABATIC DOMINO CIRCUIT

By researching the ternary counter and low power circuit design method, a novel design of low power ternary Domino counter on switch-level is proposed. Firstly, the switch-level structure expression of ternary loop operation circuit with enable pin is derived according to the switch-signal theory, and the one bit ternary counter is obtained combining the ternary adiabatic Domino literal operation circuit and buffer. Then the switch-level structure expression of enable signal circuit is derived, and the four bits ternary counter is obtained by cascade connection. Finally, the circuit is simulated by Spice tool and the output waveforms transform in proper order indicating that the logic function is correct. The energy consumption of the four bits ternary adiabatic Domino counter is 63% less than the conventional Domino counterpart.

Temperature and Process Variations Aware Dual Threshold Voltage Footed Domino Circuits Leakage Management

Considering the effect of temperature and process variations, the inputs and clock signals combination sleep state dependent leakage current characteristics is analyzed and the optimal sleep state is examined in sub-65nm dual threshold voltage （V1） footed domino circuits. HSPICE simulations based on 65nm and 45nm BSIM4 models show that the proposed CLIL state （the clock signal and inputs are all low） is the optimal state to reduce the leakage current of the high fan-in footed domino circuits at high temperature and almost all footed domino circuits at room temperature, as compared to the conventional CHIL state （the clock signal is high and inputs are all low） and the CHIH state （the clock signal and inputs are all high）. Further, the influence of the process variations on the leakage current characteristics of the dual V1 footed domino circuits is evaluated. At last, temperature and process variation aware new low leakage current setup guidelines are provided.

A Novel High-Performance Lekage-Tolerant, Wide Fan-In Domino Logic Circuit in Deep-Submicron Technology

As technology shrinks in modern era the demand on high speed, low power consumption and small chip area in microprocessors is come into existence. In this paper we have presented a new class of domino circuit design for low power consumption, faster circuit speed and high performance. Due to wide fan-in domino logic, its logic gate suffer from noise sensitivity, if we improve sensitivity, sub-threshold and gate oxide leakage current dominate in evaluation network, which increases the power consumption and reduces the performance of the circuit. The proposed circuit improves the dynamic power consumption and reduces the delay which improves the speed of the circuit. Simulation is performed in BISM4 Cadence environment at 65 nm process technology, with supply voltage 1 V at 100 MHz frequency and bottleneck operating temperature of 27°C with CL = 1 fF. From the result average power improvement by proposed circuit 1 & 2 for 8 input OR gate is 10.1%, 15.28% SFLD, 48.56%, 51.49% CKD, 55.17%, 57.71% HSD and improvement of delay is 1.10%, 12.76% SFLD, 19.13%, 28.63% CKD, 4.32%, 15.59% HSD, 19.138%, 44.25% DFD respectively.

High-Speed,Robust CMOS Dynamic Circuit Design

A novel circuit with a narrow pulse driving structure is proposed for enhancing the noise immunity and improving the performance of wide fan-in dynamic circuits. Also,an analytical mode that agrees well with simulations is presented for transistor sizing. Simulation results show that an improvement of up to 12% over the conventional technique at 1GHz is obtained with this circuit,which can run 1.6 times faster than the existing technique with the same noise immunity.

三值绝热多米诺文字运算电路开关级设计

通过对绝热多米诺电路和多值电路的研究,提出一种新颖的低功耗三值文字运算电路的开关级设计方案。该方案首先通过开关—信号理论推导出逻辑0和2的文字运算电路开关级结构式及电路;然后利用三种文字运算之间互斥与互补的约束关系得到逻辑1的文字运算输出信号,同时通过波形转换电路使电路的输出转换为较规则的缓变梯形波;最后利用Spice软件对所设计的电路进行仿真,结果显示所设计的三值绝热多米诺文字运算电路具有正确的逻辑功能,与常规多米诺三值文字运算电路相比,能耗节省约39%。

低功耗、高性能多米诺电路电荷自补偿技术

提出了一种电荷自补偿技术来降低多米诺电路的功耗,并提高了电路的性能.采用电荷自补偿技术设计了具有不同下拉网络(PDN)和上拉网络(PUN)的多米诺电路,并分别基于65,45和32nmBSIM4SPICE模型进行了HSPICE仿真.仿真结果表明,电荷自补偿技术在降低电路功耗的同时,提高了电路的性能.与常规多米诺电路技术相比,采用电路自补偿技术的电路的功耗延迟积(PDP)的改进率可达42.37%.此外,以45nmZipperCMOS全加器为例重点介绍了功耗分布法,从而优化了自补偿路径,达到了功耗最小化的目的.最后,系统分析了补偿通路中晶体管宽长比,电路输入矢量等多方面因素对补偿通路的影响.

三值绝热多米诺加法器开关级设计

通过对绝热多米诺电路和加法器的研究,该文提出一种新颖低功耗三值加法器的开关级设计方案。该方案首先利用开关-信号理论,结合绝热多米诺电路结构特点,推导出三值加法器本位和电路与进位电路的开关级结构式,由此得到一位三值加法器单元电路;然后通过单元电路的级联得到四位三值绝热多米诺加法器;最后,利用Spice软件对所设计的电路进行模拟,结果显示所设计的四位三值绝热多米诺加法器具有正确的逻辑功能,与四位常规多米诺三值加法器相比,能耗节省约61%。

一种容忍老化的多米诺门

负偏置温度不稳定性引起的晶体管老化已经成为影响集成电路可靠性的重要因素。高扇入多米诺或门是高性能集成电路中常用的动态电路,而负偏置温度不稳定性降低了多米诺或门的噪声容限并增大了其传输时延。本文提出了保持器和反相器均带有补偿晶体管的多米诺或门结构,通过开启补偿电路,使电路在老化以后仍然能够保持其抗干扰能力和传输延时,有效的延长了多米诺电路的使用寿命。

三值绝热多米诺T运算电路设计

通过对多值逻辑和绝热多米诺电路工作原理及结构的研究,提出三值绝热多米诺T运算电路的设计方案.该方案首先将三值T运算定义与三值文字运算相结合,得到基于文字运算的T运算定义式;然后以开关信号理论为指导,推导出逻辑0与逻辑2选通电路的开关级表达式,并利用文字运算互斥互补关系,得到逻辑1选通电路的开关级表达式;最后根据这些表达式进一步实现了三值绝热多米诺T运算电路.经HSPICE仿真验证,该电路具有正确的逻辑功能及低功耗特性.

一种位级流水线乘法器的设计

本文提出一种位级流水线乘法器的设计方法。在算法上考虑了无符号数与符号数各种组态的乘法运算;采用并行的半脉动阵列结构,节省了大量寄存器;使用带寄存的多米诺电路型式,减少了器件数、提高了速度并降低了功耗。按这种方法设计的8×8乘法器所需器件数少于3000个,采用2μmCMOS工艺可以达到100MHz以上的流水线工作频率。

三值绝热多米诺可逆计数器设计

通过对可逆计数器和绝热多米诺电路结构及工作原理的研究,提出一种三值绝热多米诺可逆计数器的设计方案。该方案首先以开关信号理论为指导,设计具有置位复位功能的三值绝热多米诺D触发器;然后分别设计三值绝热多米诺正反循环门电路与进位借位电路来实现计数器正反计数和级联;最后,在此基础上实现四位三值绝热多米诺可逆计数器。HSPICE仿真结果表明所设计的电路具有正确的逻辑功能和低功耗特性。

动态CMOS多米诺逻辑电路的研究

主要对导致动态CMOS多米诺电路失效的原因进行详细的描述,并讨论了解决电路失效问题的若干方案,从而有效地提高了动态CMOS多米诺逻辑电路在实际应用中的可靠性和稳定性.

用EMODL实现的高速低功耗流水线乘法器

实现快速、低功耗以及节省面积的乘法器对高性能微处理器 (例如 DSP和 RISC)而言是至关重要的。文中详尽论述了新型的增强型多输出多米诺逻辑 ( EMODL)及其 n-MOS赋值树的尺寸优化方法 ,并用它实现了高速低功耗 2 0× 2 0 bit流水线乘法器。最后 ,通过 HSPICE仿真 ,确认了该乘法器结构的优越性 :流水线等待时间小 ( 2倍于系统时钟 )、运算速度高 ( 10 0 MOPS)以及低功耗 ( 2 3 .94m W)

用于高速运算单元的时钟延迟动态多米诺逻辑电路的设计

时钟延迟多米诺逻辑是一种自定时的动态逻辑。时钟延迟多米诺逻辑门的输出信号是单向跳变的,但它可以提供倒相和非倒相的输出。使用这种动态逻辑可以大大提高运算电路的速度。本文通过一个64位的快速并行加法器的实现说明时钟延迟多米诺的特性及其设计方法。这个快速并行加法器用于高性能的64位微处理器的运算单元中。采用O.25μmCMOS工艺设计了这个加法器。加法器在最坏情况下的运算时间是700ps。这个时钟延迟多米诺加法器比使用相同单元库和技术的静态逻辑加法器快2.3倍。

一种适用于折叠插值型ADC的新型编码器

提出了一种新的适用于折叠插值型ADC的高速低功耗的编码器。该编码器使用异或-或算法完成码制转换,并且利用新的串并联多米诺电路来实现。另外,还提出了一种新的宽范围的误差校正和位同步方法应用于此编码器中。仿真结果表明,此种新型编码器的功耗延迟积比常用的ROM编码器降低了约56%,而且更适用于较高位数的折叠插值型ADC中。

一种多米诺逻辑电路抗辐照加固方法

设计了一种用于电流舵DAC电流开关的高速编码逻辑电路.为了实现高运算速率,该电路采用多米诺结构;为了增强抗辐照能力,采用电阻电容双互锁结构进行加固。通过远程测试平台进行抗单粒子效应实测,普通电路在LET值为37.2 MeV·cm/mg条件下,在离子总注量累积4.3×10^(6)ions/cm^(2)时,软错误次数便达到100次;而加固后的电路在同样的LET值下,离子总注量累积到10^(7)ions/cm^(2)时,软错误次数仅为24次,抗SET及SEU能.力大大加强.

Design of ternary low-power Domino JKL flip-flop and its application

By researching the ternary flip-tlop and the adiabatic Domino circuit,a novel design of low-power ternary Domino JKL flip-flop on the switch level is proposed.First,the switch-level structure of the ternary adiabatic Domino JKL flip-flop is derived according to the switch-signal theory and its truth table.Then the ternary loop operation circuit and ternary reverse loop operation circuit are achieved by employing the ternary JKL tlip-tlop. Finally,the circuit is simulated by using the Spice tool and the results show that the logic function is correct. The energy consumption of the ternary adiabatic Domino JKL flip-flop is 69%less than its conventional Domino counterpart.

A low-leakage and NBTI-mitigated N-type domino logic

NBTI-induced transistor aging has become a prominent factor affecting the reliability of circuits. Reducing leakage consumption is one of the major design goals. Domino logic circuits are applied extensively in high-performance integrated circuits. A circuit technique for mitigating NBTI-induced degradation and reduce standby leakage current is presented in this paper. Two transistors are added to the standard domino circuit to pull both the dynamic node and the output up to VDo, which puts both the keeper and the inverter pMOS transistor into recovery mode in standby mode. Due to the stack effect, leakage current is reduced by the all-0 input vector and the added transistors. Experimental results reveal up to 33% NBTI-induced degradation reduction and up to 79% leakage current reduction.